Abstract
When exposed to stressful conditions, eukaryotic cells respond by inducing the formation of cytoplasmic ribonucleoprotein complexes called stress granules. Stress granules are thought to have a protective function but their exact role is still unclear. Here we use C. elegans to study two proteins that have been shown to be important for stress granule assembly in human cells: PQN-59, the ortholog of human UBAP2L, and GTBP-1, the ortholog of the human G3BP1 and G3BP2 proteins. Both proteins fall into stress granules in the embryo and in the germline when C. elegans is exposed to stressful conditions. None of the two proteins is essential for the assembly of stress induced granules, but the granules formed in absence of PQN-59 or GTBP-1 are less numerous and dissolve faster than the ones formed in control embryos. Despite these differences, pqn-59 or gtbp-1 mutant embryos do not show a higher sensitivity to stress than control embryos. pqn-59 mutants display reduced progeny and a high percentage of embryonic lethality, phenotypes that are not dependent on stress exposure and that are not shared with gtbp-1 mutants. Our data indicate that both GTBP-1 and PQN-59 contribute to stress granule formation but that PQN-59 is, in addition, required for C. elegans development.
Author summary The formation of so-called stress granules is an adaptive response that cells and organisms put into action to cope with changes in internal and environmental conditions and thus to survive to stressful conditions. Although it is generally thought that stress granule formation protects cells from stress-related damage, the exact role of stress granules in cells and organisms is not well understood. Moreover, the mechanisms governing stress granule assembly, and if and how the ability to form stress granules is important for C. elegans development is still unclear.
Our work focuses on two conserved proteins, known to be involved in stress granule assembly in mammalian cells, and investigates their role in C. elegans embryos. We find that these proteins are important but not essential to assemble stress-induced granules in C. elegans. We moreover did not observe a different sensitivity to stress exposure between wild-type and mutant developing embryos, suggesting that at least in these conditions these proteins do not exert a protective role.