Li Ding

A proteogenomic analysis of cervical cancer reveals therapeutic and biological insights

Although the incidence of cervical cancer (CC) has been reduced in high-income countries due to human papillomavirus (HPV) vaccination and screening strategies, it remains a significant public health issue that poses a threat to women's health in low-income countries. Here, we perform a comprehensive proteogenomic profiling of CC tumors obtained from 139 Chinese women. Integrated proteogenomic analysis links genetic aberrations to downstream pathogenesis-related pathways and reveals the landscape of HPV-associated multi-omic changes. EP300 is found to enhance the acetylation of FOSL2-K222, consequently accelerating the malignant proliferation of CC cells. Proteomic stratification identifies three patient subgroups with distinct features in prognosis, genetic alterations, immune infiltration, and post-translational modification regulations. PRKCB is further identified as a potential radioresponse-related biomarker of CC patients. This study provides a valuable public resource for researchers and clinicians to delve into the molecular basis of CC, to identify potential treatments and to ultimately advance clinical practice.

Chemoradiation Reprograms Tumor Cells and the Immune Microenvironment in Cervical Cancer

Abstract Despite advances in screening and prevention, cervical cancer remains a leading cause of cancer-related deaths worldwide, underscoring the need for better treatments. In this study, we conducted a multicohort longitudinal study of human cervical tumors and the tumor microenvironment during chemoradiotherapy (CRT) and integrated RNA sequencing and single-cell transcriptomics to define the cellular and molecular programs shaping cell interactions and how CRT alters them. The analysis identified multiple therapeutic targets in CRT-resistant tumors, notably including MDM2, a key mediator of radiation responses in tumor and immune cells. MDM2 inhibition enhanced the effects of radiotherapy in human papillomavirus (HPV)–positive, TP53 wild-type cervical cancer cells; improved radiation response; and reshaped the immune landscape in preclinical models. These findings highlight the potential of combining MDM2 inhibition with CRT to overcome resistance and improve patient outcomes. The insights into therapy-induced changes in tumor and immune compartments could guide improved strategies against treatment-resistant HPV-positive cancers. Significance: Mapping of the impact of chemoradiation on cellular interactions in cervical cancer reveals how treatment reshapes the tumor microenvironment and highlights targets for developing future immunotherapeutic approaches. See related commentary by Klopp, p. 1540