CDK2 regulates collapsed replication fork repair in CCNE1-amplified ovarian cancer cells via homologous recombination

Enhancing the detection of clinically relevant biomarkers in advanced uterine and tubo-ovarian carcinomas through genome-wide analysis

BACKGROUND

Advanced-stage tube-ovarian cancers (TOC) and uterine cancers (UC) significantly contribute to cancer mortality. While surgery achieves clinical remission in most cases, recurrence often necessitates systemic therapy. Recent molecular phenotype studies have advanced targeted therapies. We employed whole genome sequencing (WGS) to investigate biomarkers in gynecologic malignancies.

DESIGN

Ninety-one tumor samples (45 TOC, 46 UC) were analyzed for germline mutations, somatic driver mutations, rearrangements, genome-wide signatures, and molecular phenotypes. A WGS-based high-confidence classifier for homologous recombination deficiency (HRD) was applied. Genomic profiles were correlated with clinical outcomes.

RESULTS

The HRD phenotype was identified in serous carcinoma components, with 50 % of HRD cases showing BRCA1/2 wildtype (33 %) or variants of unknown significance (17 %). HRD correlated with better overall survival in tubo-ovarian serous carcinoma and was linked to responses to platinum therapy and PARP inhibitors. Endometrioid carcinomas showed no HRD phenotype despite BRCA1/2 variants. CDK12-type genomic instability (10 %) occurred in cases with CDK12 rearrangements, and CCNE1 gain (8 %) was observed in CCNE1-amplified cases, independent of copy number. In endometrioid carcinoma, mismatch repair (MMR) deficiency single base substitution signatures, particularly SBS44, contributed to high tumor mutation burden (TMB). Ultra-high TMB was found in two cases with pathogenic POLE and POLQ mutations, exhibiting multiple SBS signatures, including MMR deficiency.

CONCLUSION

Comprehensive genomic profiling of advanced-stage TOC and UC via WGS reveals key biomarkers and therapeutic targets, enhancing diagnostic accuracy and advancing personalized medicine in gynecological cancers.

Targeting CDK2 to combat drug resistance in cancer therapy

Drug resistance remains a major obstacle in cancer treatment, leading to treatment failures and high mortality rates. Despite advancements in therapies, overcoming resistance requires a deeper understanding of its mechanisms. This review highlights CDK2's pivotal role in both intrinsic and acquired resistance, and its potential as a therapeutic target. Cyclin E upregulation, which partners with CDK2, is linked to poor prognosis and resistance across various cancers. Specifically, amplifications of CCNE1/CCNE2 are associated with resistance to targeted therapies, immunotherapy, endocrine therapies and chemo/radiotherapy. Given CDK2's involvement in resistance mechanisms, investigating its role presents promising opportunities for developing novel strategies to combat resistance and improve treatment outcomes.

Multimodal Spatial Profiling Reveals Immune Suppression and Microenvironment Remodeling in Fallopian Tube Precursors to High-Grade Serous Ovarian Carcinoma

High-Grade Serous Ovarian Cancer (HGSOC) originates from fallopian tube (FT) precursors. However, the molecular changes that occur as precancerous lesions progress to HGSOC are not well understood. To address this, we integrated high-plex imaging and spatial transcriptomics to analyze human tissue samples at different stages of HGSOC development, including p53 signatures, serous tubal intraepithelial carcinomas (STIC), and invasive HGSOC. Our findings reveal immune modulating mechanisms within precursor epithelium, characterized by chromosomal instability, persistent interferon (IFN) signaling, and dysregulated innate and adaptive immunity. FT precursors display elevated expression of MHC-class I, including HLA-E, and IFN-stimulated genes, typically linked to later-stage tumorigenesis. These molecular alterations coincide with progressive shifts in the tumor microenvironment, transitioning from immune surveillance in early STICs to immune suppression in advanced STICs and cancer. These insights identify potential biomarkers and therapeutic targets for HGSOC interception and clarify the molecular transitions from precancer to cancer.

Key Proteins of Replication Stress Response and Cell Cycle Control as Cancer Therapy Targets

Replication stress (RS) is a characteristic state of cancer cells as they tend to exchange precision of replication for fast proliferation and increased genomic instability. To overcome the consequences of improper replication control, malignant cells frequently inactivate parts of their DNA damage response (DDR) pathways (the ATM-CHK2-p53 pathway), while relying on other pathways which help to maintain replication fork stability (ATR-CHK1). This creates a dependency on the remaining DDR pathways, vulnerability to further destabilization of replication and synthetic lethality of DDR inhibitors with common oncogenic alterations such as mutations of TP53, RB1, ATM, amplifications of MYC, CCNE1 and others. The response to RS is normally limited by coordination of cell cycle, transcription and replication. Inhibition of WEE1 and PKMYT1 kinases, which prevent unscheduled mitosis entry, leads to fragility of under-replicated sites. Recent evidence also shows that inhibition of Cyclin-dependent kinases (CDKs), such as CDK4/6, CDK2, CDK8/19 and CDK12/13 can contribute to RS through disruption of DNA repair and replication control. Here, we review the main causes of RS in cancers as well as main therapeutic targets-ATR, CHK1, PARP and their inhibitors.