Diverse stresses and aging result in changes in expression levels of microRNAs, suggesting a role for these posttrancriptional regulators of gene expression in stress modulation and longevity. Earlier studies demonstrated a central role for the miR-34 family in promoting cell cycle arrest and cell death following stress in human cells. However, the biological significance of this response was unclear, because wildtype and miR-34 family knockouts tested under a variety of stress conditions showed no difference in cell survival in vitro or in vivo. Here, we addressed this question in C. elegans by analyzing the effect of different stress conditions on phenotype, transcriptome and
mir-34 expression in animals deficient in or overexpressing
mir-34. We showed that
mir-34 upregulation is necessary for developmental arrest, correct morphogenesis, and adaptation to a lower metabolic state to protect animals against stress-related damages. Either deletion or overexpression of
mir-34 lead to impaired stress response, which can largely be explained by perturbations in a DAF-16/FOXO target genes. We demonstrate that
mir-34 expression is regulated by the insulin signaling pathway via a negative feedback loop between miR-34 and DAF-16/FOXO. We propose that
mir-34 provides robustness to stress response programs by controlling noise in the DAF-16/FOXO-regulated gene network.