Rps15 mutation drives B cell malignancy through translational rewiring, oxidative stress and genomic instability

Ribosomal protein mutations are increasingly associated with cancer risk and thought to perturb ribosome function. At the same time, they reportedly activate p53, a critical anti-cancer barrier. To determine how these mutations overcome this protective block to enable tumorigenesis, we generated an in vivo model of the hotspot Rps15-S138F mutation identified as a putative driver of chronic lymphocytic leukemia. Under pre-leukemic conditions, this mutation induced protein instability, ribosome biogenesis defects and altered translation resulting in oxidative stress, DNA damage and induction of a p53-dependent response that promote initial cellular hypo-proliferation. However, aged mice with mutated Rps15 eventually developed B-cell leukemia (37% penetrance), which exhibited increased Myc activity with strong pro-survival and proliferation signatures. Mutant Rps15 thus induces both hypo- and hyper-proliferative signals, initially weighted towards cell cycle arrest; and that through translational rewiring, oxidative stress, DNA damage response defects and genomic instability set the stage for the acquisition of additional driving mutations, such as TP53 deletion, that can overcome this cell cycle block to trigger tumorigenesis. Overall design: Paired RNA-seq and ribo-seq profiling of age-matched Rps15-S138F mutant and wildtype mice