Chromosome instability and aneuploidy have long posed a conundrum in cancer biology, profoundly shaping tumor genomes yet remaining challenging to decode functionally. In a groundbreaking study published in Nature, Al-Zahrani et al. unveil a novel approach, CRISPR-KOALA, that systematically links large-scale chromosomal alterations to specific cancer-driving genes in basal-like breast cancer (BLBC).
BLBC, a highly aggressive subtype characterized by extensive copy-number alterations (CNAs), often harbors arm-level chromosomal imbalances whose contribution to tumorigenesis remains elusive. The researchers developed CRISPR-KOALA to conduct high-throughput bidirectional genetic screens directly in immunocompetent mouse models, overcoming previous barriers related to the complexity and scale of genes affected by aneuploidy.
By focusing on the ten most frequent human chromosome-arm alterations seen in BLBC, the team screened over 3,700 mouse orthologues of genes located on these arms. The screen identified 90 putative cancer driver genes—a majority of which had not been previously linked to cancer—revealing a diverse functional landscape shaping tumor biology. Among the implicated pathways were key signaling networks such as MAPK, HIPPO, and WNT, highlighting the heterogeneity intrinsic to BLBC progression.
Strikingly, manipulating these driver genes in Trp53-mutant mouse models was sufficient to bypass the need for whole-arm CNAs, suggesting that tumors exploit specific genes within broad chromosomal alterations to fuel oncogenesis. This finding challenges the traditional view that arm-level aneuploidies function merely as genomic chaos, instead presenting them as evolutionary selections for particular drivers.
One gene, PLGRKT, localized on chromosome 9p, emerged as a potent oncogene. The team showed that PLGRKT promotes tumor growth by enhancing mitochondrial robustness and boosting reactive oxygen species detoxification. This mechanistic insight connects chromosomal instability not only to genetic selection but also to metabolic adaptations that support cancer cell survival under stress.
Overall, this study delivers a transformative platform and a compendium of cancer drivers that illuminate how aneuploidy sculpts tumor heterogeneity. By delineating driver genes nested within widespread CNAs, it provides an invaluable resource for targeting breast cancer’s genetic complexity with greater precision.
The implications extend beyond breast cancer, offering a blueprint for dissecting arm-level aneuploidy in diverse malignancies. As cancer therapies increasingly focus on genetic vulnerabilities, CRISPR-KOALA represents a leap toward untangling the intricate link between chromosome-level alterations and oncogenic processes.
This work underscores the power of integrating genomic data with functional genetics in vivo, setting the stage for novel drug targets and therapeutic strategies aimed at the underexplored realm of aneuploidy-driven tumorigenesis.
Subject of Research: Chromosome instability and cancer driver genes in basal-like breast cancer
Article Title: Aneuploidy selects for the acquisition of driver genes in breast cancer
Article References:
Al-Zahrani, K.N., Langille, E.R., Nurtanto, J. et al. Aneuploidy selects for the acquisition of driver genes in breast cancer. Nature (2026). https://doi.org/10.1038/s41586-026-10752-9
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s41586-026-10752-9
Tags: aneuploidy in breast cancerbasal-like breast cancer (BLBC)cancer genomicscancer signaling pathways (MAPKchromosome instabilitychromosome-arm alterationscopy-number alterations (CNAs)CRISPR-KOALA gene screeninghigh-throughput genetic screensHIPPOmouse models of breast cancertumor evolution and progressiontumor-driving genesWNT)



