Abstract
Adaptive homeostasis enables rapid cellular signaling, leading to transcriptional and translational modifications (Davies, 2016) [1]. The Proteasome is one of the main cellular proteolytic enzymes that plays an essential role in the rapid clearance of oxidatively damaged cellular proteins, and is highly responsive to oxidative stress. Upon exposure to even very low, signaling levels of oxidants, the predominant form of the Proteasome becomes the ATP-independent 20S proteasome that enables rapid clearance of damaged proteins. Subsequently there is also a concurrent upregulation of de novo 20S proteasome synthesis. These cellular adaptations not only ensure effective and efficient removal of damaged proteins, but prepare cells to better cope with future, more severe oxidative insults. Male and female Drosophila melanogaster fruit flies were pretreated with an adaptive amount of an oxidant (10 µM hydrogen peroxide or 0.5 µM paraquat) to assess the changes in proteolytic capacity and the role of the 20S proteasome. Additionally, the adaptive signaling by non-damaging amounts of hydrogen peroxide or paraquat) were used to assess changes in male and female fruit flies, following a subsequent more toxic amount of the two oxidants. Further analysis and detailed results about the adaptive role of the 20S proteasome in multiple D. melanogaster strains can be found in "Sexual Dimorphism in Oxidant-Induced Adaptive Homeostasis in Multiple Wild-Type D. melanogaster Strains" (Pomatto et al., 2018) [2].