Characterization of chronic low-level proteasome inhibition on neural homeostasis

Increasing evidence suggests that proteasome inhibition plays a causal role in promoting the neurodegeneration and neuron death observed in multiple disorders, including Alzheimer's disease (AD) and Parkinson's disease (PD). The ability of severe and acute inhibition of proteasome function to induce neuron death and neuropathology similar to that observed in AD and PD is well documented. However, at present the effects of chronic low-level proteasome inhibition on neural homeostasis has not been elucidated. In order to determine the effects of chronic low-level proteasome inhibition on neural homeostasis, we conducted studies in individual colonies of neural SH-SY5Y cells that were isolated following continual exposure to low concentrations (100 nm) of the proteasome inhibitor MG115. Clonal cell lines appeared morphologically similar to control cultures but exhibited significantly different rates of both proliferation and differentiation. Elevated levels of protein oxidation and protein insolubility were observed in clonal cell lines, with all clonal cell lines being more resistant to neural death induced by serum withdrawal and oxidative stress. Interestingly, clonal cell lines demonstrated evidence for increased macroautophagy, suggesting that chronic low-level proteasome inhibition may cause an excessive activation of the lysosomal system. Taken together, these data indicate that chronic low-level proteasome inhibition has multiple effects on neural homeostasis, and suggests that studying the effects of chronic low-level proteasome inhibition may be useful in understanding the relationship between protein oxidation, protein insolubility, proteasome function, macroautophagy and neural viability in AD and PD.     

Degradation of oxidized proteins by the 20S proteasome

Oxidatively modified proteins are continuously produced in cells by reactive oxygen and nitrogen species generated as a consequence of aerobic metabolism. During periods of oxidative stress, protein oxidation is significantly increased and may become a threat to cell survival. In eucaryotic cells the proteasome has been shown (by purification of enzymatic activity, by immunoprecipitation, and by antisense oligonucleotide studies) to selectively recognize and degrade mildly oxidized proteins in the cytosol, nucleus, and endoplasmic reticulum, thus minimizing their cytotoxicity. From in vitro studies it is evident that the 20S proteasome complex actively recognizes and degrades oxidized proteins, but the 26S proteasome, even in the presence of ATP and a reconstituted functional ubiquitinylating system, is not very effective. Furthermore, relatively mild oxidative stress rapidly (but reversibly) inactivates both the ubiquitin activating/conjugating system and 26S proteasome activity in intact cells, but does not affect 20S proteasome activity. Since mild oxidative stress actually increases proteasome-dependent proteolysis (of oxidized protein substrates) the 20S 'core' proteasome complex would appear to be responsible. Finally, new experiments indicate that conditional mutational inactivation of the E1 ubiquitin-activating enzyme does not affect the degradation of oxidized proteins, further strengthening the hypothesis that oxidatively modified proteins are degraded in an ATP-independent, and ubiquitin-independent, manner by the 20S proteasome. More severe oxidative stress causes extensive protein oxidation, directly generating protein fragments, and cross-linked and aggregated proteins, that become progressively resistant to proteolytic digestion. In fact these aggregated, cross-linked, oxidized proteins actually bind to the 20S proteasome and act as irreversible inhibitors. It is proposed that aging, and various degenerative diseases, involve increased oxidative stress (largely from damaged and electron 'leaky' mitochondria), and elevated levels of protein oxidation, cross-linking, and aggregation. Since these products of severe oxidative stress inhibit the 20S proteasome, they cause a vicious cycle of progressively worsening accumulation of cytotoxic protein oxidation products.     

Regulation of proteasome-mediated protein degradation during oxidative stress and aging

Protein degradation is a physiological process required to maintain cellular functions. There are distinct proteolytic systems for different physiological tasks under changing environmental and pathophysiological conditions. The proteasome is responsible for the removal of oxidatively damaged proteins in the cytosol and nucleus. It has been demonstrated that proteasomal degradation increases due to mild oxidation, whereas at higher oxidant levels proteasomal degradation decreases. Moreover, the proteasome itself is affected by oxidative stress to varying degrees. The ATP-stimulated 26S proteasome is sensitive to oxidative stress, whereas the 20S form seems to be resistant. Non-degradable protein aggregates and cross-linked proteins are able to bind to the proteasome, which makes the degradation of other misfolded and damaged proteins less efficient. Consequently, inhibition of the proteasome has dramatic effects on cellular aging processes and cell viability. It seems likely that during oxidative stress cells are able to keep the nuclear protein pool free of damage, while cytosolic proteins may accumulate. This is because of the high proteasome content in the nucleus, which protects the nucleus from the formation and accumulation of non-degradable proteins. In this review we highlight the regulation of the proteasome during oxidative stress and aging.     

Ump1 extends yeast lifespan and enhances viability during oxidative stress: Central role for the proteasome?

Increasing evidence suggests that the proteasome may play an important role in both oxidative stress response and cellular aging, although considerable controversy exists as to the exact role the proteasome plays in each of these paradigms. In the present study we examined the contribution of impaired proteasome function to the regulation of oxidative damage (oxidized protein levels) following the administration of oxidative stressors, and to the cytotoxicity observed in aging and oxidatively challenged cells. In these studies the preservation of proteasome-mediated protein degradation was achieved via increased expression of the proteasome assembly protein Ump1. We observed that Saccharomyces cerevisiae transformed to express increased levels of Ump1 exhibited increased viability in response to a variety of oxidative stressors (menadione, hydrogen peroxide, 4-hydroxynonenal). The increased viability observed in each of these paradigms was associated with an enhanced preservation of proteasome-mediated protein degradation, consistent with the preservation of proteasome function being sufficient to ameliorate oxidative stress-induced cytotoxicity. Interestingly, cells expressing Ump1 were observed to initially have robust elevations in oxidized protein levels following the addition of oxidative stressors, but exhibited a significantly reduced level of oxidized proteins following the removal of oxidative stressors. Cells expressing elevated levels of Ump1 also exhibited an enhanced preservation of proteasome-mediated protein degradation, and enhanced viability during stationary-phase aging. Taken together these data strongly support a role for the proteasome serving as a central regulator of cellular viability during oxidative stress and during aging.     

Proteasome inhibition in oxidative stress neurotoxicity: implications for heat shock proteins

Recent studies have demonstrated that inhibition of the proteasome, an enzyme responsible for the majority of intracellular proteolysis, may contribute to the toxicity associated with oxidative stress. In the present study we demonstrate that exposure to oxidative injury (paraquat, H(2)O(2), FeSO(4)) induces a rapid increase in reactive oxygen species (ROS), loss of mitochondrial membrane potential, inhibition of proteasome activity, and induction of cell death in neural SH-SY5Y cells. Application of proteasome inhibitors (MG115, epoxomycin) mimicked the effects of oxidative stressors on mitochondrial membrane potential and cell viability, and increased vulnerability to oxidative injury. Neural SH-SY5Y cells stably transfected with human HDJ-1, a member of the heat shock protein family, were more resistant to the cytotoxicity associated with oxidative stressors. Cells expressing increased levels of HDJ-1 displayed similar degrees of ROS formation following oxidative stressors, but demonstrated a greater preservation of mitochondrial function and proteasomal activity following oxidative injury. Cells transfected with HDJ-1 were also more resistant to the toxicity associated with proteasome inhibitor application. These data support a possible role for proteasome inhibition in the toxicity of oxidative stress, and suggest heat shock proteins may confer resistance to oxidative stress, by preserving proteasome function and attenuating the toxicity of proteasome inhibition.     

RNA interference toward UMP1 induces proteasome inhibition in Saccharomyces cerevisiae: evidence for protein oxidation and autophagic cell death

The proteasome is a large intracellular protease that is responsible for a large portion of intracellular proteolysis, in particular the degradation of a majority of short-lived and oxidized proteins. Inhibition of proteasome function occurs in response to multiple stressors, with proteasome inhibition sufficient for the induction of a wide range of cytotoxic processes. Although considerable advances have been made in the understanding of the proteasome, and the effects of proteasome inhibition, our understanding of these topics in Saccharomyces cerevisiae has been slowed by the inability of proteasome inhibitors to penetrate and/or be retained in S. cerevisiae. Expression of UMP1 is necessary for proteasome assembly in S. cerevisiae, and in the present study we examined the effectiveness of RNA interference for UMP1 as a means of achieving proteasome inhibition in S. cerevisiae. Induction of RNA interference for UMP1 resulted in a dramatic decrease in UMP1 at the protein level, which was not observed in cells transformed with control vector. RNA interference caused an impairment in proteasome function, and increase in protein oxidation, with proteins involved in both stress response and energy metabolism showing increased oxidation. Interestingly, RNA interference induced cell death that seemed to be autophagic in nature, suggesting possible cross talk between the proteasome and the autophagic proteolytic pathways. Taken together, these data indicate that RNA interference may be a useful model with which to study the effects of proteasome inhibition in S. cerevisiae and demonstrate the ability of proteasome inhibition to induce cytotoxic alterations in S. cerevisiae.     

Oxidative modification of proteasome: identification of an oxidation-sensitive subunit in 26 S proteasome

Reactive oxygen species (ROS) have the potential to damage cellular components, such as protein, resulting in loss of function and structural alteration of proteins. The oxidative process affects a variety of side amino acid groups, some of which are converted to carbonyl compounds. We have previously shown that a prostaglandin D2 metabolite, 15-deoxy-delta(12,14)-prostaglandin J2 (15d-PGJ2), is the potent inducer of intracellular oxidative stress on human neuroblastoma SH-SY5Y cells [Kondo, M., Oya-Ito, T., Kumagai, T., Osawa, T., and Uchida, K. (2001) Cyclopentenone prostaglandins as potential inducers of intracellular oxidative stress, J. Biol. Chem. 276, 12076-12083]. In the present study, to elucidate the molecular mechanism underlying the oxidative stress-mediated cell degeneration, we analyzed the protein carbonylation on SH-SY5Y cells when these cells were submitted to an endogenous inducer of ROS production. Upon exposure of SH-SY5Y cells to this endogenous electrophile, we observed significant accumulation of protein carbonyls within the cells. Proteomic analysis of oxidation-sensitive proteins showed that the major intracellular target of protein carbonylation was one of the regulatory subunits in 26 S proteasome, S6 ATPase. Accompanied by a dramatic increase in protein carbonyls within S6 ATPase, the electrophile-induced oxidative stress exerted a significant decrease in the S6 ATPase activities and a decreased ability of the 26 S proteasome to degrade substrates. Moreover, in vitro oxidation of 26 S proteasome with a metal-catalyzed oxidation system also confirmed that S6 ATPase represents the most oxidation-sensitive subunit in the proteasome. These and the observation that down-regulation of S6 ATPase by RNA interference resulted in the enhanced accumulation of ubiquitinated proteins suggest that S6 ATPase is a molecular target of ROS under conditions of electrophile-induced oxidative stress and that oxidative modification of this regulatory subunit of proteasome may be functionally associated with the altered recognition and degradation of proteasomal substrates in the cells.     

Morphine and HIV-Tat increase microglial-free radical production and oxidative stress: possible role in cytokine regulation

Opiate abuse alters the progression of human immunodeficiency virus and may increase the risk of neuroAIDS. As neuroAIDS is associated with altered microglial reactivity, the combined effects of human immunodeficiency virus-Tat and morphine were determined in cultured microglia. Specifically, experiments determined the effects of Tat and morphine on microglial-free radical production and oxidative stress, and on cytokine release. Data show that combined Tat and morphine cause early and synergistic increases in reactive oxygen species, with concomitant increases in protein oxidation. Furthermore, combined Tat and morphine, but not Tat or morphine alone, cause reversible decreases in proteasome activity. The effects of morphine on free radical production and oxidative stress are prevented by pre-treatment with naloxone, illustrating the important role of opioid receptor activation in these phenomena. While Tat is well known to induce cytokine release from cultured microglia, morphine decreases Tat-induced release of the cytokines tumor necrosis factor-α and interleukin-6, as well as the chemokine monocyte chemoattractant protein-1 (MCP-1). Finally, experiments using the reversible proteasome inhibitor MG115 show that temporary, non-cytotoxic decreases in proteasome activity increase protein oxidation and decrease tumor necrosis factor-α, interleukin-6, and MCP-1 release from microglia. Taken together, these data suggest that oxidative stress and proteasome inhibition may be involved in the immunomodulatory properties of opioid receptor activation in microglia.     

Role of increased expression of the proteasome in the protective effects of sulforaphane against hydrogen peroxide-mediated cytotoxicity in murine neuroblastoma cells

The 26S proteasome is responsible for degradation of abnormal proteins and may play a role in cell survival upon oxidative stress. The indirect antioxidant sulforaphane (SFN) protects animal tissues from chemical toxicants by increasing the expression of several families of Nrf2-regulated genes. The role of induction of the 26S proteasome in cytoprotection by SFN was investigated in murine neuroblastoma Neuro2A cells. SFN enhanced the expression of the catalytic subunits of the proteasome, as well as proteasomal peptidase activities in these cells. Such treatment with SFN protected cells from hydrogen peroxide-mediated cytotoxicity in a manner dependent on proteasomal function. Inhibition of proteasome activities using pharmacological interventions significantly attenuated the protective effects of SFN against hydrogen peroxide cytotoxicity, as well as protein oxidation. Moreover, overexpression of the catalytic subunit PSMB5 enhanced proteasome function and led to elevated resistance against hydrogen peroxide toxicity and extent of protein oxidation compared to blank-plasmid-transfected cells. Pretreatment of PSMB5-overexpressing cells with SFN did not further enhance this resistance. Collectively, these results suggest that the cytoprotective effects of SFN against oxidative stress are in part due to up-regulation of the proteasome system. Therefore, inducers of proteasome expression may ameliorate the accumulation of damaged proteins associated with neurodegeneration and other diseases in whose etiologies protein oxidation plays a role.     

Dopamine induces proteasome inhibition in neural PC12 cell line

The autoxidation and enzymatic catabolism of dopamine results in the generation of reactive oxygen species (ROS), which may possibly contribute to oxidative stress in multiple neurodegenerative disorders. Recent studies indicate that proteasome inhibition occurs in numerous neurodegenerative conditions, possibly as the result of oxidative stress, although the effects of dopamine on proteasome activity have not been determined. In the present study we examined the effects of dopamine on proteasome activity in the neural PC12 cell line. Application of dopamine induced a dose- and time-dependent decrease in proteasome activity, which occurred prior to cell death. Application of an antioxidant (gluthathione monoethyl ester), monoamine oxidase inhibitors (deprenyl, clogyline, paragyline), or an inhibitor of dopamine uptake (nomifensine) attenuated dopamine toxicity and dopamine-induced proteasome impairment. Application of the proteasome inhibitor lactacystin increased the toxicity of dopamine and the levels of protein oxidation following administration of dopamine. Together, these data indicate that dopamine induces proteasome inhibition that is dependent, in part, on ROS and dopamine uptake, and suggest a possible role for proteasome inhibition in dopamine toxicity.     

Proteasome inhibition represses unfolded protein response and Nox4, sensitizing vascular cells to endoplasmic reticulum stress-induced death

BACKGROUND: Endoplasmic reticulum (ER) stress has pathophysiological relevance in vascular diseases and merges with proteasome function. Proteasome inhibition induces cell stress and may have therapeutic implications. However, whether proteasome inhibition potentiates ER stress-induced apoptosis and the possible mechanisms involved in this process are unclear. METHODOLOGY/PRINCIPAL FINDINGS: Here we show that proteasome inhibition with MG132, per se at non-lethal levels, sensitized vascular smooth muscle cells to caspase-3 activation and cell death during ER stress induced by tunicamycin (Tn). This effect was accompanied by suppression of both proadaptive (KDEL chaperones) and proapoptotic (CHOP/GADD153) unfolded protein response markers, although, intriguingly, the splicing of XBP1 was markedly enhanced and sustained. In parallel, proteasome inhibition completely prevented ER stress-induced increase in NADPH oxidase activity, as well as increases in Nox4 isoform and protein disulfide isomerase mRNA expression. Increased Akt phosphorylation due to proteasome inhibition partially offset the proapoptotic effect of Tn or MG132. Although proteasome inhibition enhanced oxidative stress, reactive oxygen species scavenging had no net effect on sensitization to Tn or MG132-induced cell death. CONCLUSION/RELEVANCE: These data indicate unfolded protein response-independent pathways whereby proteasome inhibition sensitizes vascular smooth muscle to ER stress-mediated cell death. This may be relevant to understand the therapeutic potential of such compounds in vascular disease associated with increased neointimal hyperplasia.     

Proteasome inactivation upon aging and on oxidation-effect of HSP 90

Increases of oxidatively modified protein in the cell have been associated with the aging process. Such an accumulation of damaged protein may be the result of increase in the rate of protein oxidation and/or decrease in the rate of degradation of oxidized protein. The multicatalytic proteinase or proteasome is known to be the major proteolytic system involved in the removal of oxidized protein. We have reported that, after isolation of the 20S proteasome from the liver of young and old male Fischer 344 rat, out of the three peptidase activities (chymotrypsin-like, trypsin-like and peptidyl-glutamyl peptide hydrolase) we assayed with fluorogenic peptides, the peptidyl-glutamyl peptide hydrolase activity was declining with age to a value approximately 50% of that observed for protease purified from young rats. The proteasome was subjected to metal catalyzed oxidation to determine the susceptibility of the different peptidase activities to oxidative inactivation. Both trypsin-like and peptidyl-glutamyl peptide hydrolase activities were found sensitive to oxidation. Treatment of the proteasome with 4-hydroxy-2-nonenal, a major lipid peroxidation product, was also found to inactivate the trypsin-like activity. However, the trypsin-like activity was protected from inactivation by metal catalyzed oxidation in proteasome preparations contaminated with HSP 90, a protein that often copurifies with the proteasome. Upon addition of HSP 90 to pure 20S active proteasome, the trypsin-like activity was protected from inactivation by metal catalyzed oxidation and from inactivation by treatment with 4-hydroxy-2-nonenal. These results suggest a possible intervention of HSP 90 in response to oxidative stress in preventing the inactivation of the proteasome by oxidative damage. Abbreviations: AAF-amc – Ala-Ala-Phe-7-amido-4-methylcoumarin; LSTR-amc – N-t-Boc-Leu-Ser-Thr-Arg-7-amido-4-methylcoumarin; LLE-na – Leu-Leu-Glu-b-naphthylamide; HSP 90: heat shock protein 90, MCP – multicatalytic proteinase or 20S proteasome.     

Reactive oxygen species downregulate glucose transport system in retinal endothelial cells

Retinal endothelial cells are believed to play an important role in the pathogenesis of diabetic retinopathy. In previous studies, we and others demonstrated that glucose transporter 1 (GLUT1) is downregulated in response to hyperglycemia. Increased oxidative stress is likely to be the event whereby hyperglycemia is transduced into endothelial cell damage. However, the effects of sustained oxidative stress on GLUT1 regulation are not clearly established. The objective of this study is to evaluate the effect of increased oxidative stress on glucose transport and on GLUT1 subcellular distribution in a retinal endothelial cell line and to elucidate the signaling pathways associated with such regulation. Conditionally immortalized rat retinal endothelial cells (TR-iBRB) were incubated with glucose oxidase, which increases the intracellular hydrogen peroxide levels, and GLUT1 regulation was investigated. The data showed that oxidative stress did not alter the total levels of GLUT1 protein, although the levels of mRNA were decreased, and there was a subcellular redistribution of GLUT1, decreasing its content at the plasma membrane. Consistently, the half-life of the protein at the plasma membrane markedly decreased under oxidative stress. The proteasome appears to be involved in GLUT1 regulation in response to oxidative stress, as revealed by an increase in stabilization of the protein present at the plasma membrane and normalization of glucose transport following proteasome inhibition. Indeed, levels of ubiquitinated GLUT1 increase as revealed by immunoprecipitation assays. Furthermore, data indicate that protein kinase B activation is involved in the stabilization of GLUT1 at the plasma membrane. Thus subcellular redistribution of GLUT1 under conditions of oxidative stress is likely to contribute to the disruption of glucose homeostasis in diabetes.     

Comparison of rat liver and brain proteasomes for oxidative stress-induced inactivation: Influence of ageing and dietary restriction

The present study examined brain and liver derived proteasome complexes to elucidate if there is a differential susceptibility in proteasome complexes from these tissues to undergo inactivation following exposure to oxidative stressors. It then examined the influence of ageing and dietary restriction (DR) on the observed proteasome inactivation. Studies used a filtration based methodology that allows for enrichment of proteasome complexes with less tissue than is required for traditional chromatography procedures. The results indicate that the brain has much lower levels of overall proteasome activity and exhibits increased sensitivity to hydrogen peroxide mediated inactivation as compared to proteasome complexes derived from the liver. Interestingly, the brain proteasome complexes did not appear to have increased susceptibility to 4-hydroxynonenal (HNE)-induced inactivation. Surprisingly, ageing and DR induced minimal effects on oxidative stress mediated proteasome inhibition. These results indicate that the brain not only has lower levels of proteasome activity compared to the liver, but is also more susceptible to inactivation following exposure to some (but certainly not all) oxidative stressors. This data also suggest that ageing and DR may not significantly modulate the resistance of the proteasome to inactivation in some experimental settings.     

Proteasome modulates mitochondrial function during cellular senescence

Proteasome plays fundamental roles in the removal of oxidized proteins and in the normal degradation of short-lived proteins. Previously we have provided evidence that the impairment in proteasome observed during the replicative senescence of human fibroblasts has significant effects on MAPK signaling, proliferation, life span, senescent phenotype, and protein oxidative status. These studies have demonstrated that proteasome inhibition and replicative senescence caused accumulation of intracellular protein carbonyl content. In this study, we have investigated the mechanisms by which proteasome dysfunction modulates protein oxidation during cellular senescence. The results indicate that proteasome inhibition during replicative senescence has significant effects on intra- and extracellular ROS production in vitro. The data also show that ROS impaired the proteasome function, which is partially reversible by antioxidants. Increases in ROS after proteasome inhibition correlated with a significant negative effect on the activity of most mitochondrial electron transporters. We propose that failures in proteasome during cellular senescence lead to mitochondrial dysfunction, ROS production, and oxidative stress. Furthermore, it is likely that changes in proteasome dynamics could generate a prooxidative condition at the immediate extracellular microenvironment that could cause tissue injury during aging, in vivo.     

Methamphetamine oxidatively damages parkin and decreases the activity of 26S proteasome in vivo

Methamphetamine (METH) is toxic to dopaminergic (DAergic) terminals in animals and humans. An early event in METH neurotoxicity is an oxidative stress followed by damage to proteins and lipids. The removal of damaged proteins is accomplished by the ubiquitin-proteasome system (UPS) and the impairment of this system can cause neurodegeneration. Whether dysfunction of the UPS contributes to METH toxicity to DAergic terminals has not been determined. The present investigation examined the effects of METH on functions of parkin and proteasome in rat striatal synaptosomes. METH rapidly modified parkin via conjugation with 4-hydroxy-2-nonenal (4-HNE) to decrease parkin levels and decreased the activity of the 26S proteasome while simultaneously increasing chymotrypsin-like activity and 20S proteasome levels. Prior injections of vitamin E diminished METH-induced changes to parkin and the 26S proteasome as well as long-term decreases in DA and its metabolites' concentrations in striatal tissue. These results suggest that METH causes lipid peroxidation-mediated damage to parkin and the 26S proteasome. As the changes in parkin and 26S occur before the sustained deficits in DAergic markers, an early loss of UPS function may be important in mediating the long-term degeneration of striatal DAergic terminals via toxic accumulation of parkin substrates and damaged proteins.     

Specific SKN-1/Nrf stress responses to perturbations in translation elongation and proteasome activity

SKN-1, the Caenorhabditis elegans Nrf1/2/3 ortholog, promotes both oxidative stress resistance and longevity. SKN-1 responds to oxidative stress by upregulating genes that detoxify and defend against free radicals and other reactive molecules, a SKN-1/Nrf function that is both well-known and conserved. Here we show that SKN-1 has a broader and more complex role in maintaining cellular stress defenses. SKN-1 sustains expression and activity of the ubiquitin-proteasome system (UPS) and coordinates specific protective responses to perturbations in protein synthesis or degradation through the UPS. If translation initiation or elongation is impaired, SKN-1 upregulates overlapping sets of cytoprotective genes and increases stress resistance. When proteasome gene expression and activity are blocked, SKN-1 activates multiple classes of proteasome subunit genes in a compensatory response. SKN-1 thereby maintains UPS activity in the intestine in vivo under normal conditions and promotes survival when the proteasome is inhibited. In contrast, when translation elongation is impaired, SKN-1 does not upregulate proteasome genes, and UPS activity is then reduced. This indicates that UPS activity depends upon presence of an intact translation elongation apparatus; and it supports a model, suggested by genetic and biochemical studies in yeast, that protein synthesis and degradation may be coupled processes. SKN-1 therefore has a critical tissue-specific function in increasing proteasome gene expression and UPS activity under normal conditions, as well as when the UPS system is stressed, but mounts distinct responses when protein synthesis is perturbed. The specificity of these SKN-1-mediated stress responses, along with the apparent coordination between UPS and translation elongation activity, may promote protein homeostasis under stress or disease conditions. The data suggest that SKN-1 may increase longevity, not only through its well-documented role in boosting stress resistance, but also through contributing to protein homeostasis.