Autophagy-dependent alternative splicing event produces a more stable ribosomal protein S24 isoform that aids in hypoxic cell survival

Abstract

ABSTRACTOverlapping or convergent stress-activated molecular pathways exist to coordinate cell fate in response to stimuli such as hypoxia, oxidative stress, DNA damage, and unfolded proteins. Cells can remodel the splicing and translation machineries to mount a specialized gene expression response to certain stresses. Here, we show that hypoxic human cells in 2D and 3D culture models increase the relative abundance by 1.7- to 2.6-fold and 4.7- to 11.5-fold, respectively, of a longer mRNA variant of ribosomal protein S24 (RPS24L) compared to a shorter mRNA variant (RPS24S) by favoring the inclusion of a 22 bp cassette exon. Mechanistically, RPS24L and RPS24S are induced and repressed, respectively, by distinct parallel pathways in hypoxia: RPS24L is induced in an autophagy-dependent manner, while RPS24S is reduced by mTORC1 repression and in a HIF-dependent manner. RPS24L is a more stable mRNA in hypoxia and produces a more stable protein isoform compared to RPS24S. Cells overexpressing RPS24L display improved survival and growth in hypoxia relative to control cells and cells overexpressing RPS24S, which display impaired survival. Previous work from our group showed a correlation between RPS24L levels and tumor hypoxia in prostate cancer. These data highlight RPS24L as a stress-induced alternative splicing event that favors hypoxic cell survival, which could be exploited by cancer cells in the tumor microenvironment.