Reactive oxygen species (ROS) are well-known accelerants of aging, but, paradoxically, we show that physiological levels of ROS extend life span in pupae of the moth , resulting in the dormant state of diapause. This developmental switch appears to operate through a variant of the conventional insulin-signaling pathway, as evidenced by the facts that Akt, p-Akt, and PRMT1 are elevated by ROS, but not insulin, and that high levels of p-Akt fail to phosphorylate FoxO through PRMT1-mediated methylation. These results suggest a distinct signaling pathway culminating in the elevation of FoxO, which in turn promotes the extension of life span characteristic of diapause.
Developmental arrest (diapause) is a ‘non-aging’ state that is similar to the Caenorhabditis elegans dauer stage and Drosophila lifespan extension. Diapause results in low metabolic activity and a profound extension of insect lifespan. Here, we cloned the Helicoverpa armigera Hexokinase (HK) gene, a gene that is critical for the developmental arrest of this species. HK expression and activity levels were significantly increased in nondiapause-destined pupae compared with those of diapause-destined pupae. Downregulation of HK activity reduced cell viability and delayed pupal development by reducing metabolic activity and increasing ROS activity, which suggests that HK is a key regulator of insect development. We then identified the transcription factors Har-CREB, -c-Myc, and -POU as specifically binding the Har-HK promoter and regulating its activity. Intriguingly, Har-POU and -c-Myc are specific transcription factors for HK expression, whereas Har-CREB is nonspecific. Furthermore, Har-POU and -c-Myc could respond to ecdysone, which is an upstream hormone. Therefore, low ecdysone levels in diapause-destined individuals lead to low Har-POU and -c-Myc expression levels, ultimately repressing Har-HK expression and inducing entry into diapause or lifespan extension.
Diapause (developmental arrest) is characterized by dramatic depression of metabolic activity and profoundly extends insect lifespan, similar to the Caenorhabditis elegans dauer stage and Drosophila longevity; however, the molecular mechanism of low metabolism in insect diapause is unclear. Here, we show that HIF-1α expression is significantly increased in diapause-destined pupal brains compared to nondiapause-destined pupal brains and that HIF-1α negatively regulates mitochondrial biogenesis. HIF-1α mediates this effect by inhibiting c-Myc activity via proteasome-dependent degradation of c-Myc. The mitochondrial transcription factor A (TFAM), which encodes a key factor involved in mitochondrial transcription and mitochondrial DNA replication, is activated by the binding of c-Myc to the TFAM promoter, thereby inducing transcription. Loss of TFAM expression is a major factor contributing to reducing the mitochondrial activity. Thus, the HIF-1α-c-Myc-TFAM signaling pathway participates in the regulation of mitochondrial activity for insect diapause or lifespan extension.
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