Mitochondrial RNA Methyltransferase TRMT61B is a New, Potential Biomarker and Therapeutic Target for Highly Aneuploid Cancers

Overview

Journal Cell Death Differ

Specialty Cell Biology

Date 2022 Jul 22

PMID 35869285

Authors

Alberto Martin

Carolina Epifano

Borja Vilaplana-Marti

Ivan Hernandez

Rocio I R Macias

Angel Martinez-Ramirez

Ana Cerezo

Pablo Cabezas-Sainz

Maria Garranzo-Asensio

Sandra Amarilla-Quintana

Deborah Gomez-Dominguez

Eduardo Caleiras

Jordi Camps

Gonzalo Gomez-Lopez

Marta Gomez de Cedron

Ana Ramirez de Molina

Rodrigo Barderas

Laura Sanchez

Susana Velasco-Miguel

Ignacio Perez de Castro

Affiliations

Soon will be listed here.

Abstract

Despite being frequently observed in cancer cells, chromosomal instability (CIN) and its immediate consequence, aneuploidy, trigger adverse effects on cellular homeostasis that need to be overcome by anti-stress mechanisms. As such, these safeguard responses represent a tumor-specific Achilles heel, since CIN and aneuploidy are rarely observed in normal cells. Recent data have revealed that epitranscriptomic marks catalyzed by RNA-modifying enzymes change under various stress insults. However, whether aneuploidy is associated with such RNA modifying pathways remains to be determined. Through an in silico search for aneuploidy biomarkers in cancer cells, we found TRMT61B, a mitochondrial RNA methyltransferase enzyme, to be associated with high levels of aneuploidy. Accordingly, TRMT61B protein levels are increased in tumor cell lines with an imbalanced karyotype as well as in different tumor types when compared to control tissues. Interestingly, while TRMT61B depletion induces senescence in melanoma cell lines with low levels of aneuploidy, it leads to apoptosis in cells with high levels. The therapeutic potential of these results was further validated by targeting TRMT61B in transwell and xenografts assays. We show that TRM61B depletion reduces the expression of several mitochondrial encoded proteins and limits mitochondrial function. Taken together, these results identify a new biomarker of aneuploidy in cancer cells that could potentially be used to selectively target highly aneuploid tumors.

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