Genetic context and proliferation determine contrasting patterns of copy number amplification and loss for 5S and 45S ribosomal DNA arrays in cancer

Abstract

AbstractThe multicopy 45S ribosomal DNA (45S rDNA) array gives origin to the nucleolus, the first discovered nuclear organelle, site of Poll I 45S rRNA transcription and key regulator of cellular metabolism, DNA repair response, genome stability, and global epigenetic states. The multicopy 5S ribosomal DNA array (5S rDNA) is located on a separate chromosome, encodes the 5S rRNA transcribed by Pol III, and exhibits concerted copy number variation (cCNV) with the 45S rDNA array in human blood. Here we combined genomic data from >700 tumors and normal tissues to provide a portrait of ribosomal DNA variation in human tissues and cancers of diverse mutational signatures. We show that most cancers undergo coupled 5S rDNA array amplification and 45S rDNA loss, with abundant inter-individual variation in rDNA copy number of both arrays, and concerted modulation of 5S-45S copy number in some but not all tissues. Analysis of genetic context revealed associations between the presence of specific somatic alterations, such as P53 mutations in stomach and lung adenocarcinomas, and coupled 5S gain / 45S loss. Finally, we show that increased proliferation rates along cancer lineages can partially explain contrasting copy number changes in the 5S and 45S rDNA arrays. We suggest that 5S rDNA amplification facilitates increased ribosomal synthesis in cancer, whereas 45S rDNA loss emerges as a byproduct of transcription-replication conflict in highly proliferating tumor cells. Our results highlight the tissue- specificity of concerted copy number variation and uncover contrasting changes in 5S and 45S rDNA copy number along rapidly proliferating cell lineages.Lay SummaryThe 45S and 5S ribosomal DNA (rDNA) arrays contain hundreds of rDNA copies, with substantial variability across individuals and species. Although physically unlinked, both arrays exhibit concerted copy number variation. However, whether concerted copy number is universally observed across all tissues is unknown. It also remains unknown if rDNA copy number may vary in tissues and cancer lineages. Here we showed that most cancers undergo coupled 5S rDNA array amplification and 45S rDNA loss, and concerted 5S-45S copy number variation in some but not all tissues. The coupled 5S amplification and 45S loss is associated with the presence of certain somatic genetic variations, as well as increased cancerous cell proliferation rate. Our research highlights the tissue- specificity of concerted copy number variation and uncover contrasting changes in rDNA copy number along rapidly proliferating cell lineages. Our observations raise the prospects of using 5S and 45S ribosomal DNA states as indicators of cancer status and targets in new strategies for cancer therapy.