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miR-155 drives telomere fragility in human breast cancer by targeting TRF1.

Roberto Dinami ,
Cristiana Ercolani ,
Eleonora Petti ,
Silvano Piazza ,
Yari Ciani ,
Rosanna Sestito ,
Andrea Sacconi ,
Francesca Biagioni ,
Carlos le Sage ,
Reuven Agami ,
Roberta Benetti ,
Marcella Mottolese ,
Claudio Schneider ,
Giovanni Blandino ,
Stefan Schoeftner

Abstract

Telomeres consist of DNA tandem repeats that recruit the multiprotein complex shelterin to build a chromatin structure that protects chromosome ends. Although cancer formation is linked to alterations in telomere homeostasis, there is little understanding of how shelterin function is limited in cancer cells. Using a small-scale screening approach, we identified miR-155 as a key regulator in breast cancer cell expression of the shelterin component TERF1 (TRF1). miR-155 targeted a conserved sequence motif in the 3'UTR of TRF1, resulting in its translational repression. miR-155 was upregulated commonly in breast cancer specimens, as associated with reduced TRF1 protein expression, metastasis-free survival, and relapse-free survival in estrogen receptor-positive cases. Modulating miR-155 expression in cells altered TRF1 levels and TRF1 abundance at telomeres. Compromising TRF1 expression by elevating miR-155 increased telomere fragility and altered the structure of metaphase chromosomes. In contrast, reducing miR-155 levels improved telomere function and genomic stability. These results implied that miR-155 upregulation antagonizes telomere integrity in breast cancer cells, increasing genomic instability linked to poor clinical outcome in estrogen receptor-positive disease. Our work argued that miRNA-dependent regulation of shelterin function has a clinically significant impact on telomere function, suggesting the existence of "telo-miRNAs" that have an impact on cancer and aging.

More about this publication

Cancer research

Volume 74
Issue nr. 15
Pages 4145-56
Publication date 01-08-2014

Full text links

Publisher website (DOI) 10.1158/0008-5472.CAN-13-2038
Europe PubMed Central 24876105
Pubmed 24876105

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