TRF1依靠叉形逆转来防止人类端粒的脆弱性。

TRF1 relies on fork reversal to prevent fragility at human telomeres.

作者信息

Vaurs Mélina, Claude Eloïse, Zanella Elia, Rodrigues Joana, Nassour Joe, Karlseder Jan, Azzalin Claus M, Doksani Ylli, Decottignies Anabelle

机构信息

Genetic & Epigenetic Alterations of Genomes Unit, de Duve Institute, UCLouvain, Brussels, Belgium.

IFOM ETS - The AIRC Institute of Molecular Oncology, Milan, Italy.

出版信息

Nat Commun. 2025 Jul 11;16(1):6439. doi: 10.1038/s41467-025-61828-5.

DOI:10.1038/s41467-025-61828-5

PMID:40645989

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12254382/

Abstract

Telomeres pose challenges during replication, with converging forks unlikely to resolve issues. Depleting TRF1 results in fragile telomeres, yet its exact role in telomere replication remains unclear. In our cellular model, insufficient TRF1 density at long telomeres leads to telomere fragility that is alleviated by restoring telomeric TRF1 levels. Our findings indicate that TRF1 mitigates lagging strand telomere fragility through fork reversal in a process involving telomerase activity, rather than merely alleviating fork barriers. Additionally, TFIIH, a crucial partner of TRF1, aids in restarting replication on the leading strand after fork reversal. When fork reversal is compromised, PrimPol-mediated repriming rescues fragility at leading strand telomeres, revealing a new role for this enzyme in human telomere replication. Lastly, our findings indicate that the TRF1-mediated decrease in telomere fragility is dependent on RNA:DNA hybrids, likely facilitating fork restart.

摘要

端粒在复制过程中带来了挑战，因为汇聚的复制叉不太可能解决这些问题。耗尽TRF1会导致端粒脆弱，但其在端粒复制中的确切作用仍不清楚。在我们的细胞模型中，长端粒处TRF1密度不足会导致端粒脆弱，而通过恢复端粒TRF1水平可以缓解这种情况。我们的研究结果表明，TRF1通过涉及端粒酶活性的过程中的叉逆转来减轻滞后链端粒的脆弱性，而不仅仅是减轻叉障碍。此外，TRF1的关键伙伴TFIIH有助于在叉逆转后在前导链上重新启动复制。当叉逆转受损时，PrimPol介导的重新引发可挽救前导链端粒的脆弱性，揭示了这种酶在人类端粒复制中的新作用。最后，我们的研究结果表明，TRF1介导的端粒脆弱性降低依赖于RNA:DNA杂交体，可能有助于叉重新启动。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e769/12254382/065d062a070f/41467_2025_61828_Fig1_HTML.jpg

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TRF1依靠叉形逆转来防止人类端粒的脆弱性。

TRF1 relies on fork reversal to prevent fragility at human telomeres.

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