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#reproaging — Public Fediverse posts

Live and recent posts from across the Fediverse tagged #reproaging, aggregated by home.social.

  1. We are glad that the editorial team at #TranslationalMedicineOfAging and the peer-reviewers agreed that these were important results to disseminate to the #ReproAging research community.
    We also thank @[email protected] for supporting our work! @[email protected] 5/5

  2. We are glad that the editorial team at and the peer-reviewers agreed that these were important results to disseminate to the research community.
    We also thank @[email protected] for supporting our work! @[email protected] 5/5

  3. We are glad that the editorial team at #TranslationalMedicineOfAging and the peer-reviewers agreed that these were important results to disseminate to the #ReproAging research community.
    We also thank @[email protected] for supporting our work! @[email protected] 5/5

  4. We are glad that the editorial team at #TranslationalMedicineOfAging and the peer-reviewers agreed that these were important results to disseminate to the #ReproAging research community.
    We also thank @[email protected] for supporting our work! @[email protected] 5/5

  5. We are glad that the editorial team at #TranslationalMedicineOfAging and the peer-reviewers agreed that these were important results to disseminate to the #ReproAging research community.
    We also thank @[email protected] for supporting our work! @[email protected] 5/5

  6. As noted before, although we are disappointed that these mice cannot be used to effectively model menopausal states, we hope our observations will be useful to the #ReproAging community and avoid unnecessary waste of animals/time/resources by other labs. 4/5

  7. We confirmed that the #KOMP allele should correspond to a null allele (confirmed by Sanger🧬), but it seems that the wild-type allele is compensating in this 🐁 strain, leading to normal Fshr expression, ovarian function and absence of #ReproAging phenotype.
    3/5

  8. As noted before, although we are disappointed that these mice cannot be used to effectively model menopausal states, we hope our observations will be useful to the community and avoid unnecessary waste of animals/time/resources by other labs. 4/5

  9. We confirmed that the allele should correspond to a null allele (confirmed by Sanger🧬), but it seems that the wild-type allele is compensating in this 🐁 strain, leading to normal Fshr expression, ovarian function and absence of phenotype.
    3/5

  10. We confirmed that the #KOMP allele should correspond to a null allele (confirmed by Sanger🧬), but it seems that the wild-type allele is compensating in this 🐁 strain, leading to normal Fshr expression, ovarian function and absence of #ReproAging phenotype.
    3/5

  11. As noted before, although we are disappointed that these mice cannot be used to effectively model menopausal states, we hope our observations will be useful to the #ReproAging community and avoid unnecessary waste of animals/time/resources by other labs. 4/5

  12. As noted before, although we are disappointed that these mice cannot be used to effectively model menopausal states, we hope our observations will be useful to the #ReproAging community and avoid unnecessary waste of animals/time/resources by other labs. 4/5

  13. We confirmed that the #KOMP allele should correspond to a null allele (confirmed by Sanger🧬), but it seems that the wild-type allele is compensating in this 🐁 strain, leading to normal Fshr expression, ovarian function and absence of #ReproAging phenotype.
    3/5

  14. As noted before, although we are disappointed that these mice cannot be used to effectively model menopausal states, we hope our observations will be useful to the #ReproAging community and avoid unnecessary waste of animals/time/resources by other labs. 4/5

  15. We confirmed that the #KOMP allele should correspond to a null allele (confirmed by Sanger🧬), but it seems that the wild-type allele is compensating in this 🐁 strain, leading to normal Fshr expression, ovarian function and absence of #ReproAging phenotype.
    3/5

  16. Previous tweetorial on the preprint below - briefly, we did not observe any indication of accelerated #ReproAging in the #KOMP Fshr allele, contrary to previous work (on a distinct allele), based on breeding, endocrine markers and histology.
    2/5 twitter.com/BBParis1984/status

  17. Previous tweetorial on the preprint below - briefly, we did not observe any indication of accelerated in the Fshr allele, contrary to previous work (on a distinct allele), based on breeding, endocrine markers and histology.
    2/5 twitter.com/BBParis1984/status

  18. Previous tweetorial on the preprint below - briefly, we did not observe any indication of accelerated #ReproAging in the #KOMP Fshr allele, contrary to previous work (on a distinct allele), based on breeding, endocrine markers and histology.
    2/5 twitter.com/BBParis1984/status

  19. Previous tweetorial on the preprint below - briefly, we did not observe any indication of accelerated #ReproAging in the #KOMP Fshr allele, contrary to previous work (on a distinct allele), based on breeding, endocrine markers and histology.
    2/5 twitter.com/BBParis1984/status

  20. Previous tweetorial on the preprint below - briefly, we did not observe any indication of accelerated #ReproAging in the #KOMP Fshr allele, contrary to previous work (on a distinct allele), based on breeding, endocrine markers and histology.
    2/5 twitter.com/BBParis1984/status

  21. We hope that this study will be a useful resource for #ReproAging research and #TE Biology!
    We also thank @[email protected], our🐠🧙‍♂️#AriAdler and talented #qbio and #mcb undergrad #AlanXu and #KatelynHsu for their help on this study! 9

  22. We hope that this study will be a useful resource for research and Biology!
    We also thank @[email protected], our🐠🧙‍♂️ and talented and undergrad and for their help on this study! 9

  23. We hope that this study will be a useful resource for #ReproAging research and #TE Biology!
    We also thank @[email protected], our🐠🧙‍♂️#AriAdler and talented #qbio and #mcb undergrad #AlanXu and #KatelynHsu for their help on this study! 9

  24. We hope that this study will be a useful resource for #ReproAging research and #TE Biology!
    We also thank @[email protected], our🐠🧙‍♂️#AriAdler and talented #qbio and #mcb undergrad #AlanXu and #KatelynHsu for their help on this study! 9

  25. We hope that this study will be a useful resource for #ReproAging research and #TE Biology!
    We also thank @[email protected], our🐠🧙‍♂️#AriAdler and talented #qbio and #mcb undergrad #AlanXu and #KatelynHsu for their help on this study! 9

  26. We were curious about how #TEs would be impacted by #ReproAging, since #TE reactivation is frequent during somatic aging. Because of transgenerational mutagenic potential, dedicated safeguards evolved to keep #TEs in check in the #germline, notably through the #PIWI pathway. 3/n

  27. We were curious about how would be impacted by , since reactivation is frequent during somatic aging. Because of transgenerational mutagenic potential, dedicated safeguards evolved to keep in check in the , notably through the pathway. 3/n

  28. We were curious about how #TEs would be impacted by #ReproAging, since #TE reactivation is frequent during somatic aging. Because of transgenerational mutagenic potential, dedicated safeguards evolved to keep #TEs in check in the #germline, notably through the #PIWI pathway. 3/n

  29. We were curious about how #TEs would be impacted by #ReproAging, since #TE reactivation is frequent during somatic aging. Because of transgenerational mutagenic potential, dedicated safeguards evolved to keep #TEs in check in the #germline, notably through the #PIWI pathway. 3/n

  30. We were curious about how #TEs would be impacted by #ReproAging, since #TE reactivation is frequent during somatic aging. Because of transgenerational mutagenic potential, dedicated safeguards evolved to keep #TEs in check in the #germline, notably through the #PIWI pathway. 3/n

  31. Really excited to share our latest work, on deciphering #TE control 🧬 during #ReproAging ♀️♂️ in #AfricanTurquoiseKillifish 🐟 [ATK], online today at @[email protected]! This was spearheaded by talented #DrBryanTeefy in the lab. @[email protected] A 🧵 1/n
    genome.cshlp.org/content/early

  32. Really excited to share our latest work, on deciphering control 🧬 during ♀️♂️ in 🐟 [ATK], online today at @[email protected]! This was spearheaded by talented in the lab. @[email protected] A 🧵 1/n
    genome.cshlp.org/content/early

  33. Really excited to share our latest work, on deciphering #TE control 🧬 during #ReproAging ♀️♂️ in #AfricanTurquoiseKillifish 🐟 [ATK], online today at @[email protected]! This was spearheaded by talented #DrBryanTeefy in the lab. @[email protected] A 🧵 1/n
    genome.cshlp.org/content/early

  34. Really excited to share our latest work, on deciphering #TE control 🧬 during #ReproAging ♀️♂️ in #AfricanTurquoiseKillifish 🐟 [ATK], online today at @[email protected]! This was spearheaded by talented #DrBryanTeefy in the lab. @[email protected] A 🧵 1/n
    genome.cshlp.org/content/early

  35. Really excited to share our latest work, on deciphering #TE control 🧬 during #ReproAging ♀️♂️ in #AfricanTurquoiseKillifish 🐟 [ATK], online today at @[email protected]! This was spearheaded by talented #DrBryanTeefy in the lab. @[email protected] A 🧵 1/n
    genome.cshlp.org/content/early