Novel mutations in the RECQL4 gene affect its helicase functions, interactions with the BLM helicase and chemotherapeutics-induced cell death

Title (eng)
Novel mutations in the RECQL4 gene affect its helicase functions, interactions with the BLM helicase and chemotherapeutics-induced cell death
Author
Agnieszka Kaczmarczyk
Author
Mikolaj Sokolowski
Author
Kamil Wojnicki
Author
Marta Pabis
Author
Bartosz Wojtas
Author
Iwona A. Ciechomska
Author
Katarzyna Poleszak
Author
Bartlomiej Gielniewski
Author
Sylwia K. Król
Author
Matthew Guille
Author
Sebastian Glatt
Author
Bozena Kaminska
Abstract (eng)
RecQ family of DNA helicases play pivotal roles in DNA replication, repair and responses to DNA damage or replication stress. Several human RecQ helicases are defective in diseases associated with chromosomal instability, premature aging and cancer. We recently discovered novel mutations in the RECQL4 gene in glioblastoma (GBM), the most malignant brain tumor in adults. Transcriptomic profiles of GBMs with REQCL4 mutations resembled those in REQCL4 KO glioma cells. We employ structural modelling and biochemical approaches to elucidate impacts of novel mutations on RECQL4 helicase activities. Using recombinant RECQL4P532S and RECQL4R766Q proteins we demonstrate that P532S substitution reduces the RECQL4 ability to unwind DNA and disrupts DNA-coupled ATP-hydrolysis activity. WT and mutated RECQL4 were overexpressed in RECQL4 KO glioma cells to study interactions with BLM helicases, cell viability and specific responses to UVC- and chemotherapy-induced DNA damage/repair. Overexpression of RECQL4P532S or RECQL4R766Q variants affected DNA repair and responses to chemotherapeutics in glioma cells, and RECQL4R766Q disturbed interactions with the BLM helicase. Our results reveal deleterious consequences of novel RECQL4 mutations in GBMs. The newly identified RECQL4 mutations affect RECQL4 helicases and their interactions with BLM contributing to glioma progression.
Keywords (eng)
Cancer GenomicsDNA Damage And RepairMolecular Modelling
Type (eng)
journal article
Language
[eng]
Persistent identifier
https://phaidra.vetmeduni.ac.at/o:5127
DOI
10.1038/s41420-025-02834-w
Is in series
Title (eng)
Cell Death Discovery
Volume
11
Issue
1
ISSN
2058-7716
Issued
2025
Number of pages
12
Publication
Springer
Version type (eng)
version of record (published version)
Date issued
2025
Access rights (eng)
open access
License
CC BY 4.0 International
Rights statement (eng)
© 2025, The Author(s)