Evolution of core archetypal phenotypes in progressive high grade serous ovarian cancer

Aritro Nath,Stephen J Lee,Adam L Cohen,Edward W Wang,Patrick A Cosgrove,David D.l Bowtell ,Mihaela Cristea ,Ravi Salgia,Theresa L Werner ,Elizabeth L Christie,Nadia Traficante,Benjamin J Copeland ,Ernest Han ,Philip J Moos ,Hoda Mirsafian,S K Majumdar ,Lance Pflieger,Sián Fereday ,Jeffrey T Chang,Andrea Bild

doi:10.1038/s41467-021-23171-3

Abstract

The evolution of resistance in high-grade serous ovarian cancer (HGSOC) cells following chemotherapy is only partially understood. To understand the selection of factors driving heterogeneity before and through adaptation to treatment, we profile single-cell RNA-sequencing (scRNA-seq) transcriptomes of HGSOC tumors collected longitudinally during therapy. We analyze scRNA-seq data from two independent patient cohorts to reveal that HGSOC is driven by three archetypal phenotypes, defined as oncogenic states that describe the majority of the transcriptome variation. Using a multi-task learning approach to identify the biological tasks of each archetype, we identify metabolism and proliferation, cellular defense response, and DNA repair signaling as consistent cell states found across patients. Our analysis demonstrates a shift in favor of the metabolism and proliferation archetype versus cellular defense response archetype in cancer cells that received multiple lines of treatment. While archetypes are not consistently associated with specific whole-genome driver mutations, they are closely associated with subclonal populations at the single-cell level, indicating that subclones within a tumor often specialize in unique biological tasks. Our study reveals the core archetypes found in progressive HGSOC and shows consistent enrichment of subclones with the metabolism and proliferation archetype as resistance is acquired to multiple lines of therapy.

Highlights

The evolution of resistance in high-grade serous ovarian cancer (HGSOC) cells following chemotherapy is only partially understood
HGSOCs present a unique challenge, where the genetic heterogeneity is generally driven by structural variants (SVs) and CNVs, rather than single-gene driver mutations affecting cancer-related genes
This observation was confirmed in our Whole-genome sequencing (WGS) analysis of the temporal samples from the longitudinal cohort patients, where only truncal TP53 driver mutations were detected across most patients

Summary

Introduction

The evolution of resistance in high-grade serous ovarian cancer (HGSOC) cells following chemotherapy is only partially understood. To understand the selection of factors driving heterogeneity before and through adaptation to treatment, we profile single-cell RNAsequencing (scRNA-seq) transcriptomes of HGSOC tumors collected longitudinally during therapy. Using a multi-task learning approach to identify the biological tasks of each archetype, we identify metabolism and proliferation, cellular defense response, and DNA repair signaling as consistent cell states found across patients. Characterizing the key transcriptional changes in HGSOC tumor evolution is critical for understanding tumor progression and resistance to cancer therapy[6,7]. Longitudinal analysis of tumors in response to drug treatment using scRNA-seq combined with DNA sequencing has been utilized to understand the ecology and evolution of tumors along with phenotypic mechanisms that could be harnessed as potential drug targets in resistant tumors[19]. A computation framework to identify these factors was insufficient

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