Joint single cell DNA-Seq and RNA-Seq of cancer reveals subclonal signatures of genomic instability and gene expression

Noemi Andor; Billy T. Lau; Claudia Catalanotti; Vijay Kumar; Anuja Sathe; Kamila Belhocine; Tobias D. Wheeler; Andrew D. Price; Maengseok Song; Željko Džakula; Jon Sorenson; David Stafford; Zachary Bent; Laura DeMare; Lance Hepler; Susana Jett; Bill Kengli Lin; Shamoni Maheshwari; Anthony J. Makarewicz; Mohammad Rahimi; Sanjam S. Sawhney; Martin Sauzade; Joe Shuga; Katrina Sullivan-Bibee; Adam Weinstein; Wei Yang; Yifeng Yin; Matthew Kubit; Jiamin Chen; Susan M. Grimes; Carlos Jose Suarez; George A. Poultsides; Michael Schnall-Levin; Rajiv Bharadwaj; Hanlee P. Ji

doi:10.1101/445932

ABSTRACT

Sequencing the genomes of individual cancer cells provides the highest resolution of intratumoral heterogeneity. To enable high throughput single cell DNA-Seq across thousands of individual cells per sample, we developed a droplet-based, automated partitioning technology for whole genome sequencing. We applied this approach on a set of gastric cancer cell lines and a primary gastric tumor. In parallel, we conducted a separate single cell RNA-Seq analysis on these same cancers and used copy number to compare results. This joint study, covering thousands of single cell genomes and transcriptomes, revealed extensive cellular diversity based on distinct copy number changes, numerous subclonal populations and in the case of the primary tumor, subclonal gene expression signatures. We found genomic evidence of positive selection – where the percentage of replicating cells per clone is higher than expected – indicating ongoing tumor evolution. Our study demonstrates that joining single cell genomic DNA and transcriptomic features provides novel insights into cancer heterogeneity and biology.

SIGNIFICANCE We conducted a massively parallel DNA sequencing analysis on a set of gastric cancer cell lines and a primary gastric tumor in combination with a joint single cell RNA-Seq analysis. This joint study, covering thousands of single cell genomes and transcriptomes, revealed extensive cellular diversity based on distinct copy number changes, numerous subclonal populations and in the case of the primary tumor, subclonal gene expression signatures. We found genomic evidence of positive selection where the percentage of replicating cells per clone is higher than expected indicating ongoing tumor evolution. Our study demonstrates that combining single cell genomic DNA and transcriptomic features provides novel insights into cancer heterogeneity and biology.

Competing Interest Statement

Authors associated with 10X Genomics are employees. 10X Genomics developed the single cell DNA assay.

Footnotes

Correction to a co-author.

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