Nuclear Transport: A Switch for the Oxidative Stress—Signaling Circuit?

Kodiha, Mohamed; Stochaj, Ursula

doi:https://doi.org/10.1155/2012/208650

Journal of Signal Transduction

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Reactive Oxygen Species: Friends and Foes of Signal Transduction

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Review Article | Open Access

Volume 2012 | Article ID 208650 | https://doi.org/10.1155/2012/208650

Nuclear Transport: A Switch for the Oxidative Stress—Signaling Circuit?

Mohamed Kodiha¹and Ursula Stochaj¹

Academic Editor: Paola Chiarugi

Received24 May 2011

Accepted05 Jul 2011

Published15 Oct 2011

Abstract

Imbalances in the formation and clearance of reactive oxygen species (ROS) can lead to oxidative stress and subsequent changes that affect all aspects of physiology. To limit and repair the damage generated by ROS, cells have developed a multitude of responses. A hallmark of these responses is the activation of signaling pathways that modulate the function of downstream targets in different cellular locations. To this end, critical steps of the stress response that occur in the nucleus and cytoplasm have to be coordinated, which makes the proper communication between both compartments mandatory. Here, we discuss the interdependence of ROS-mediated signaling and the transport of macromolecules across the nuclear envelope. We highlight examples of oxidant-dependent nuclear trafficking and describe the impact of oxidative stress on the transport apparatus. Our paper concludes by proposing a cellular circuit of ROS-induced signaling, nuclear transport and repair.

1. Introduction

1.1. Reactive Oxygen Species

Oxidative stress is generated by an increase in reactive oxygen species (ROS), either in the form of free radicals or nonradical oxidants [1, 2]. Although elevated levels of ROS can damage a wide variety of molecules, ROS production is essential to normal cell physiology [3–12]. As such, ROS participate in cell-signaling events and can function as second messengers. Moreover, ROS are generated at sites of inflammation, where they fend off microbial infections [13–16]. On the other hand, ROS are believed to contribute to aging [3–9, 12]; they are also produced in response to environmental insults, such as X-rays, UV light, ultrasound, or microwave radiation [17–19]. At the cellular level, ROS are generated as metabolic byproducts of normal biological processes, with oxidative phosphorylation in mitochondria as the primary source in eukaryotic cells [20]. Aside from the mitochondrial electron transport chain, NADPH oxidases, cyclooxygenases, lipoxygenases, xanthine oxidase, and other cellular enzymes make also important contributions to cellular ROS production [21–25].

The different types of ROS and their mode of action have been discussed in detail [1, 11, 26–30]. ROS that are particularly important to cell physiology include the hydroxyl radical •OH, superoxide anion , the nonradical hydrogen peroxide (H₂O₂), alkoxy and peroxy radicals, hypochlorous acid or peroxynitrite, and reactive sulfur species [1, 29, 31, 32]. Here, we recapitulate the properties of those ROS only that are relevant to the experiments discussed in this review.

The hydroxyl radical •OH is highly reactive and causes damage to nucleic acids and proteins, this radical also promotes lipid peroxidation [2, 12, 33]. Due to their high reactivity, hydroxyl radicals are especially harmful and considered a major cause of oxidant-induced damage [34]. The superoxide free radical can interfere with the proper function of enzymes by damaging their active sites, with cysteine residues being particularly susceptible [32]. In an experimental setting, superoxide radicals can be generated by providing xanthine oxidase with the appropriate substrates [35].

There is some debate about the impact of H₂O₂ on the cellular redox homeostasis. On one hand, H₂O₂ is not deemed a major direct threat for the cellular redox homeostasis due to its poor reactivity towards biomolecules [36]. However, H₂O₂ rapidly translocates through lipid bilayers and is a potential precursor for •OH radicals [32, 37]. Thus, high concentrations of H₂O₂ can release iron from heme proteins and catalyze the conversion of H₂O₂ to hydroxyl radicals [37]. It was also proposed that the nonradical oxidant H₂O₂ may have profound effects on redox signaling in living cells, where it alters the function of redox circuits that are composed of redox-sensitive building blocks [1]. Despite these different views on how H₂O₂ contributes to oxidant-induced damage, we and others [38–42] have used this compound extensively to examine the impact of oxidative stress on nuclear transport (see below).

1.2. Oxidative Stress and Cellular Defense Mechanisms

The appropriate response to stress is fundamental to cell survival and the recovery from disease-related or environmental damage [3, 5, 6, 9, 11]. Thus, in order to maintain redox homeostasis, the balance between production and clearance of ROS is essential. Imbalances in ROS concentration, if left without proper intervention, can interfere with a wide variety of cellular processes, leading to serious injuries and possibly cell death, either by apoptosis or necrosis [28, 43].

Upon accumulation, ROS can interact inappropriately with a large number of biomolecules, including lipids, proteins, and DNA, thereby interfering with numerous cellular functions [28, 37]. For instance, ROS may induce damage to various enzymes, leading to the partial or complete loss of their function. Notably, ROS-damaged proteins can form toxic aggregates that cause cell injury and ultimately cell death [16]. Furthermore, ROS-induced lipid peroxidation may alter the permeability of cellular membranes, potentially destroying the membrane integrity and triggering cell death [33, 44]. In addition, ROS-induced modifications of DNA can be mutagenic, possibly initiating cell transformation and promoting cancer [45].

In line with the complex pattern of damage triggered by oxidative stress, ROS accumulation contributes to the pathophysiologies of many human diseases and syndromes. In particular, oxidative stress plays a critical role in the onset and the progression of neurodegenerative disorders, diabetes, cardiovascular diseases, and nephropathy [27, 46–58].

To counteract the potential damage of elevated ROS concentrations, cells have developed different strategies that limit the action of reactive compounds and prevent their accumulation. To this end, eukaryotic cells are equipped with multiple defense mechanisms that promote the removal and inactivation of ROS in different cellular compartments [59–62]. These mechanisms rely on the coordinated action of several enzymatic systems that are able to react with and neutralize different ROS. For example, the superoxide dismutase (SOD) system is essential to redox homeostasis [11, 63–65], as it catalyzes the conversion of to H₂O₂. H₂O₂ produced by SOD can then be eliminated by the enzymatic action of catalases.

The glutathione/glutathione disulfide system (GSH/GSSG) is one of the major contributors to redox homeostasis and of particular importance to the intracellular redox state. Accordingly, glutathione is believed to be the primary defense when cells are injured by oxidative stress during ischemia/reperfusion [66, 67]. Moreover, changes in the GSH/GSSG ratio affect the intracellular redox state, and depletion of intracellular glutathione generates oxidative stress [61]. Owing to its pivotal importance to redox homeostasis, imbalance of the GSH/GSSG system has been linked to many human diseases, pathologies, and aging [11, 66, 68]. The GSH/GSSG system can be modulated experimentally, and diethyl maleate is one of compounds that deplete glutathione, thereby causing oxidative stress [38, 69]. Furthermore, the cellular redox homeostasis can also be altered by changing the activity of glutathione peroxidase, glutathione, or thioredoxin reductase.

2. Oxidative Stress and Nucleocytoplasmic Transport

2.1. Nuclear Transport of Macromolecules

Nucleocytoplasmic transport is central to the cellular homeostasis, as the proper and timely response to endogenous and environmental stimuli relies on the communication between the nucleus and cytoplasm. This applies in particular to kinases and phosphatases, many of which move in and out of the nucleus in response to oxidants or other stressors (see below). The nuclear envelope provides the barrier between these two compartments [70, 71], and macromolecules traverse the nuclear envelope via nuclear pore complexes (NPCs). Trafficking in and out of the nucleus controls signal transduction, gene expression, cell-cycle progression, and apoptosis; regulated nuclear transport is also essential for development and required for the proper response to stress [72–75]. The separation of nucleus and cytoplasm is ideal to divide signaling and other events. However, this compartmentalization can impede the intracellular communication if components of the nuclear transport apparatus are affected by ROS. This is indeed the case, as nuclear transport factors are primary cellular targets for oxidants. Before describing the impact of oxidative stress on nuclear transport, we briefly summarize those mechanisms of nuclear trafficking that are relevant to our review (Figure 1).

Figure 1

Simplified model for classical nuclear import and Crm1-mediated export, two essential transport pathways. Classical nuclear import depends on the carrier importin-β and the adaptor protein importin-α. Together, importin-α/β move NLS-containing cargos to the nucleus. The absence of RanGTP from the cytoplasm permits the assembly of import complexes in the cytoplasm. Conversely, the high RanGTP concentration in the nucleus promotes the dissociation of classical import complexes after they translocate across the NPC. RanGTP in the nucleus is also necessary to generate export complexes that contain Crm1 and NES-containing cargo. The function of Crm1 is inhibited by leptomycin B (LMB).

Although diffusion across the NPC is not simply a function of the molecular mass, most proteins that are larger than 40 kD do not efficiently diffuse across the nuclear envelope. Nevertheless, molecules exceeding the diffusion channel of the NPC can move in or out of the nucleus if they carry specialized transport signals. Nuclear localization (NLS), nuclear export (NES), or shuttling sequences serve as permanent signals that mediate targeting to the proper location. Classical NLSs are characterized by clusters of basic amino acid residues, whereas NESs are frequently enriched for leucine or isoleucine residues. However, the final destination of a macromolecule not only depends on such transport signals; the steady-state distribution is also controlled by its retention in the nuclear or cytoplasmic compartment.

Nuclear Carriers
Nuclear transport of most proteins depends on transporters of the importin-β group (also called karyopherin-β). Importin-β family members interact with their cargo either directly or through an adaptor. The latter applies to classical nuclear import, which relies on the carrier importin-β1 and its adaptor importin-α (Figure 1). Multiple isoforms of importin-α exist in higher eukaryotes, where they recognize classical NLSs in endogenous and fluorescent cargos such as NLS-mCherry (Figure 2(a)). Crm1/exportin-1 [76], another importin-β family member, moves NES-containing proteins like mCit-NES to the cytoplasm (Figure 2(b)). This transport route can be inhibited specifically with leptomycin B, a compound that covalently modifies a cysteine residue of Crm1 [77].

(a) Nuclear import

(b) Nuclear export

Figure 2

Oxidative stress inhibits classical nuclear import and Crm1-mediated export. (a) Nuclear import. HeLa cells transiently synthesizing the import substrates NLS-mCherry or GFP-tagged glucocorticoid receptor (GR-GFP) were incubated under nonstress conditions (control) or with DEM as described [69]. Note that a significant amount of the reporter proteins relocated to the cytoplasm upon oxidant treatment, indicating that classical nuclear import was inhibited. (b) Nuclear export. HeLa cells synthesizing the fluorescent reporter protein mCit-NES, a Crm1 cargo, were exposed to DEM and processed as in part a. The Crm1 export cargo was excluded from the nucleus under control conditions, but relocated to nuclei upon oxidative stress. Size bar is 20 μm.

The RanGTPase System
Carriers of the importin-β family require the small GTPase Ran and factors that modulate Ran activity. These factors include in the cytoplasm RanBP1 (Ran-binding protein 1) and the GTPase activating protein RanGAP1, with RanGAP1 binding to Nup358 at the cytoplasmic side of the NPC. By contrast, the RanGTP-binding protein RanBP3 and the guanine nucleotide exchange factor RCC1 (RanGEF) are located in the nucleus, where RCC1 binds to chromatin. The asymmetric distribution of Ran modulators generates a gradient across the nuclear envelope, with RanGTP in nuclei and RanGDP in the cytoplasm (Figure 1). This gradient provides the driving force for all importin-β dependent transport [70, 71].

Regulation of Nuclear Transport
Control of nuclear trafficking is crucial under normal, stress, and disease conditions, and it occurs on multiple levels [72, 73]. For instance, phosphorylation and other posttranslational modifications can change the transport of individual cargos [73, 78]. A more general regulation that affects multiple transport cargos is achieved by targeting components of the nuclear transport machinery. This can be accomplished by altering the localization or posttranslational modification of transport factors, and such changes are observed in response to oxidative stress [72].

The following sections summarize the effects of oxidative stress on specific cargos that are relevant to human health, the nucleocytoplasmic transport apparatus, and important signaling components. We will then build on this information to propose that the interdependence of oxidative stress, nucleocytoplasmic transport, and signaling provides a circuit that controls cell survival.

2.2. Oxidative Stress Impinges on Multiple Nuclear Cargos

As discussed above, oxidative stress causes the modification of targets in the nucleus and cytoplasm. Together, ROS-dependent modifications of cargos and the nuclear transport apparatus regulate the intracellular distribution of many of these targets. Among the oxidant-sensitive targets that translocate through NPCs are transcription factors, some of which are also implicated in the stress response. Prominent examples of transcription factors that relocate in response to oxidative stress are NF-κB and Nrf2 (NF-E2-related factor 2). The ROS-mediated redistribution of NF-κB and Nrf2 has been described extensively [80–83] and the relevant data will only be summarized here. Our discussion will focus on high-mobility group box 1 protein (HMGB1) and glycerolaldehyde-3-phosphate dehydrogenase (GAPDH) to illustrate the link between ROS, nuclear trafficking and signalling.

The role of NF-κB in immunity and inflammation is well established; however, this transcription factor is also critical for the synthesis of antioxidant proteins [80, 81]. The genes upregulated by NF-κB include MnSOD, Cu,ZnSOD, and HO-1 (heme oxygenase 1), all of which participate in antioxidant defense processes. ROS and numerous other stimuli control the intracellular distribution of NF-κB. In the absence of these stimuli, NF-κB is retained in the cytoplasm due to its association with I-κB. ROS trigger the degradation of I-κB, thereby promoting the nuclear accumulation of NF-κB and the subsequent transcription of genes that contain NF-κB response elements [81].

Nrf2 is another key player in the antioxidant response that relocates upon oxidant exposure. Under nonstress conditions, concentrations of the transcription factor Nrf2 are low, and the protein is retained in the cytoplasm owing to its association with Keap1 [82, 83]. In response to oxidative stress, a complex series of events leads to the stabilization of Nrf2 and its translocation into the nucleus. In the nucleus, Nrf2 upregulates the expression of several genes that are implicated in the antioxidant response [84]. The oxidant-induced nuclear accumulation of Nrf2 can be mediated by importin-α5/importin-β1 [85], whereas Nrf2 nuclear export is promoted by Crm1 [86]. Phosphorylation of Nrf2 likely plays a role in its nuclear import and export, with PI3 kinase possibly stimulating Nrf2 nuclear accumulation [83, 84].

More recent studies identified HMGB1 and GAPDH as redox sensitive proteins whose nucleocytoplasmic distribution is regulated by ROS and signaling [87, 88]. Like Keap1/Nrf2, HMGB1 functions as a redox sensor [87]. In nuclei, HMGB1 serves as a DNA chaperone and participates in replication, transcription, as well as DNA repair. However, HMGB1 also contributes to a variety of signaling processes, which involve HMGB1 export to the cytoplasm and its subsequent secretion. At steady-state HMGB1 shuttles between the nucleus and cytoplasm, but hyperacetylation triggers its relocation to the cytosol [89]. It was speculated that lysine acetylation reduces the number of positive charges and thus interferes with nuclear import of the protein [89]. Karyopherin-α1, a member of the importin-α family, was identified as a binding partner that supports in vitro nuclear import of HMGB1, most likely in conjunction with importin-β1 [90]. The interaction of HMGB1 with karyopherin-α1 can be abrogated by phosphorylation, and modification of two NLS segments is necessary to relocate HMGB1 to the cytoplasm [90]. Taken together, a combination of acetylation and phosphorylation controls HMBG1 nuclear accumulation. These posttranslational modifications likely prevent the recognition of HMBG1 by the classical import apparatus.

Nuclear export of HMGB1 is at least in part mediated by Crm1, as leptomycin B drastically reduced HMGB1 exit from the nucleus [89]. Treatment with H₂O₂ upregulated the interaction Crm1/HMBG1 and relocated HMBG1 to the cytoplasm for secretion [91]. This oxidant-dependent secretion was sensitive to JNK and MEK inhibitors, in line with the idea that several members of the MAP kinase families control HMBG1 movement from the nucleus to the cytoplasm and its subsequent release. In other studies, IL-1β-dependent ERK1/2 activation increased the concentration of Crm1 and led to HMBG1 accumulation in the cytoplasm [92]. Whether H₂O₂ treatment, which activates ERK1/2, has the same effect on Crm1 levels is an exciting question that has to be answered in the future.

In recent years GAPDH has emerged as an enzyme that is involved in diverse cellular processes [88, 93]. Thus, GAPDH not only functions in glycolysis in the cytoplasm, but also plays additional important roles in other compartments of the cell, including the nucleus [88, 94–101]. The nuclear accumulation of GAPDH is controlled by posttranslational modifications and the interaction with different binding partners in the cytoplasm and nucleus. In response to oxidative stress, GAPDH undergoes S-nitrosylation and subsequent association with Siah. The GAPDH-Siah complex then moves into the nucleus, where it participates in the regulation of gene expression and apoptosis [88]. GAPDH nuclear accumulation depends on the acetylation of three lysine residues by the acetyltransferase p300 [101]. Furthermore, O-GlcNAc glycosylation of GAPDH occurs close to the Siah-binding site, and this modification promotes GAPDH nuclear accumulation [100]. Although not tested by the authors, O-GlcNAc modifications rise in response to oxidative stress [102] and could therefore assist in the stress-induced nuclear accumulation of GAPDH. Interestingly, the nucleocytoplasmic trafficking of GAPDH has been linked to several signaling pathways. In particular, activation of AMPK promoted the nuclear accumulation of GAPDH, whereas signaling through the PI3 kinase → Akt module is required for Crm1-dependent nuclear export [96].

The intracellular location of GAPDH is directly relevant to human health (see below). For example, when in the nucleus GAPDH might contribute to the initiation of apoptosis in brain cells. Moreover, the oxidant-induced changes in GAPDH subcellular localization probably play a role in the pathology of Alzheimer disease [93]. GAPDH is also critical to the development of diabetic complications, and changes in its nuclear accumulation might aggravate diabetic retinopathy [97].

Taken together, there is a growing list of proteins whose nucleocytoplasmic distribution is controlled by the intracellular redox homeostasis. This regulation frequently relies on posttranslational modifications, which can alter the interaction of a particular cargo with its carrier or the retention in nuclear and cytoplasmic compartments.

2.3. Oxidative Stress as a Key Player in Human Health

The cellular damage caused by oxidative stress promotes the onset as well as progression of several diseases and pathophysiologies. Thus, oxidative stress plays a critical role in neurodegenerative disorders, cardiovascular and metabolic diseases, as well as the complications associated with diabetes. Here, we focus on some examples that highlight the adverse effects of oxidative stress on human health.

Oxidative Stress and Neurodegenerative Diseases
The human brain is particularly vulnerable to oxidant-induced damage owing to high oxygen consumption, lipids rich in polyunsaturated fatty acids, high amounts of redox-active transition metals, and relatively poor defense against oxidative stress [30, 48, 103]. Several lines of evidence implicate oxidative stress in the neuronal damage that accompanies neurodegenerative disorders [25, 30, 34, 103, 104]. For instance, analysis of cerebrospinal fluid, plasma, and urine samples or postmortem brain specimens demonstrated the increase in oxidative damage in patients suffering from amyotrophic lateral sclerosis [105], Friedreich ataxia, Parkinson, Alzheimer, and Huntington diseases [30, 48, 103]. Oxidant-induced injury is elevated in the brain at early stages of these diseases, supporting the model that oxidative stress contributes to the etiology of neurodegeneration. In line with this hypothesis, mitochondrial dysfunction and oxidative damage to mitochondrial proteins are shared features of different neurodegenerative diseases [25, 30, 34, 103]. Animal models further support this idea, as inhibitors of mitochondrial function can induce some of the pathologies associated with Parkinson disease [34]. In addition, proteomics identified a large number of proteins that show increased oxidative damage in patients suffering from various forms of neurodegeneration. These proteins include several enzymes that are critical to oxidative phosphorylation and glycolysis. Notably, when compared to control subjects GAPDH oxidation was increased in Alzheimer and Parkinson patients; GAPDH was also affected in ALS mouse models [103]. This is significant, because GAPDH and its subcellular trafficking are of particular importance to human metabolism and the pathologies associated with neurodegenerative diseases. As such, oxidative damage not only reduces the enzymatic activity of GAPDH in Alzheimer disease, but also supports the association with Siah and the subsequent translocation of the GAPDH-Siah complex to the nucleus (see above). In Alzheimer disease, both GAPDH expression and nitrosylation are increased, probably leading to elevated concentrations of GAPDH-Siah in the nucleus, which in turn promotes apoptosis [93]. Taken together, the oxidant-induced changes in GAPDH enzyme activity and intracellular distribution will reduce the energy supply and advance apoptosis in the brain of Alzheimer patients. Since GAPDH is an established target of oxidative damage in several neurodegenerative diseases [103], it is possible that its oxidant-dependent change in nuclear transport and the subsequent increase in cell death are common to multiple forms of neurodegeneration. Interestingly, GAPDH also plays a critical role in the development of diabetic complications.

Oxidative Stress and Diabetes
Oxidative stress is crucial to the etiology of diabetes mellitus and the ensuing damage to different tissues and organs [27, 49, 55, 106, 107]. Thus, oxidative stress can alter insulin signaling by targeting insulin receptor and insulin receptor substrates or through the activation of ser/thr kinases that regulate insulin signaling [55]. In this scenario, the ROS-induced changes to the insulin signaling pathway will advance insulin resistance and the subsequent development of diabetes. PI3 kinase and the MAP kinases ERK1/2 are major components of insulin-mediated signaling. Interestingly, signaling through these kinases is also modulated by oxidative stress and regulates nuclear trafficking (see below).

Oxidative stress not only promotes the development of diabetes, but diabetes also triggers the increase in oxidative stress due to elevated blood glucose and free fatty acids. Such disease-induced ROS production further exacerbates cellular damage and contributes to diabetic complications. In the following, we discuss some of the routes that generate oxidative stress in the diabetic patient [49, 55, 106–108].

Hyperglycemia rises intracellular glucose concentrations and the subsequent production of pyruvate, which is ultimately metabolized via the tricarboxylic acid cycle. As a result of the high abundance of pyruvate, increased amounts of NADH and FADH₂ are generated by the tricarboxylic acid cycle. Both NADH and FADH₂ enter into the mitochondrial electron transport chain, but their excess interferes eventually with the proper transfer of electrons. As a consequence of this overload, superoxide production by mitochondria increases and promotes cellular damage, especially in the diabetic vasculature [109, 110]. The importance of mitochondria in hyperglycemia-induced injuries was demonstrated experimentally, as inhibitors of the electron transport chain, upregulation of the uncoupling protein UCP1, or mitochondrial SOD ameliorated some of the damage [49, 106].

The excess of mitochondrial superoxide, combined with other hyperglycemia-induced changes, culminates in secondary diabetic complications. In particular, diabetic nephropathy, retinopathy, neuropathy, and cardiomyopathy arise from the modulation of multiple biochemical pathways, some of which alter the cellular redox homeostasis [27, 49, 107]. For example, upon diabetes, the abundance of intracellular glucose and glycolytic metabolites leads to the increased production of sorbitol and other sugar alcohols by the polyol pathway. This generation of sugar alcohols mediated by members of the aldo-keto reductase family relies on the conversion of NADPH to NADP⁺ [49]. Since NADPH is necessary to generate GSH from GSSG, excessive NADPH consumption will compromise the antioxidant defense and promote ROS-induced damage.

Moreover, ROS concentrations can also be elevated by hyperglycemia-dependent changes in cell signaling. As described above, GAPDH is sensitive to oxidative stress, and the inhibition of GAPDH by ROS increases intracellular concentrations of triose phosphate, a precursor of the PKC activator diacylglycerol. Hence, hyperglycemia triggers PKC activation, thereby changing the signaling events in the diabetic retina, heart, and endothelial cells [49, 106]. Moreover, this hyperglycemia-induced PKC activation is particularly detrimental to the kidney, as it stimulates ROS production by NAD(P)H oxidases and advances diabetic nephropathy [106, 111].

Like other forms of stress, diabetes modulates the nucleocytoplasmic distribution of transcription factors, with NF-κB as a prominent example [112]. Similarly, high glucose concentrations accumulated GAPDH in the nucleus of bovine retinal endothelial cells [97], where it could contribute to the progression of diabetic retinopathy.

The downstream effects of hyperglycemia further include changes in the posttranslational modification of proteins. Thus, elevated glucose concentrations raise the amount of fructose-6-phosphate that enters the hexosamine pathway [27, 106], which in turn increases the production of UDP-N-Acetylglucosamine and the subsequent O-GlcNAc modification of proteins. These changes are important to nuclear transport, because nucleoporins are well established targets for O-GlcNAc-glycosylation.

In summary, oxidative stress is implicated in different pathophysiological conditions, some of which alter the proper coordination of nuclear and cytoplasmic events. As discussed in the following section, ROS impinge on the nuclear transport apparatus and thereby modify the communication between nucleus and cytoplasm.

2.4. Nuclear Transport and Redox Homeostasis

Changes in cell physiology affect nucleocytoplasmic trafficking in a wide variety of eukaryotes, and the effects of oxidative stress on the nuclear transport apparatus have been analyzed during the past years. We have shown for the yeast S. cerevisiae and mammalian culture cells that different forms of stress, including oxidants, heat, and nutrient deprivation inhibit classical nuclear import and export [38, 39, 69, 72, 79, 113–121]. Our previous studies examined the impact of severe and mild oxidative stress. While severe oxidative stress was produced with high concentrations of H₂O₂ [39], mild oxidative stress was generated by the oxidant diethyl maleate, DEM [69]. Under severe stress conditions, cells underwent apoptosis, but a large fraction of cells survived the milder stress inflicted with DEM [69]. Nevertheless, Figures 2 and 3 show that DEM treatment diminished nuclear transport of both fluorescent reporter proteins and endogenous cargos [69, 79, 117]. This is not simply a consequence of stress-induced permeabilization of nuclear envelopes, because the barrier function of nuclear membranes was preserved under these conditions [122]. Since fluorescent reporter proteins like NLS-mCherry or mCit-NES do not contain nuclear or cytoplasmic retention signals, it was reasonable to assume that their stress-induced redistribution reflected changes to the transport apparatus. As described below, such changes were indeed reported by different laboratories, both for severe and mild forms of oxidative stress.

(a)

(b)

Figure 3

Oxidative stress interferes with importin-α1-dependent import of endogenous cargos. The import of two endogenous proteins, the RNA-binding protein HuR and galectin-3, was monitored in HeLa cells under the conditions described for Figure 2(a). Importin-α1 promotes nuclear import of both proteins. HuR and galectin-3 were visualized by indirect immunofluorescence and nuclei were stained with DAPI [69]. HuR was nuclear in control cells and redistributed to the cytoplasm of stressed cells, where it accumulated in stress granules (SGs). Similarly, galectin-3 was more concentrated in the nuclei of control cells and relocated to the cytoplasm upon DEM treatment. Arrows indicate the position of some of the SGs.

A common consequence of H₂O₂-induced severe oxidative stress is the collapse of the nucleocytoplasmic Ran GTPase gradient in growing cells (Figure 4); this collapse contributes to classical import inhibition [35, 38, 39, 121]. In addition, three key components of the transport apparatus, nucleoporin Nup153, the carrier importin-β1, and importin-α1 (Figure 4), redistributed when cells were treated with H₂O₂ [39]. Aside from transport factor redistribution, H₂O₂ also caused the degradation of Ran, Nup153 and importin-β1, both by proteasome and caspase-dependent mechanisms. In addition to growing cells, the consequences of H₂O₂ incubation were also examined in vitro. In these experiments, oxidant treatment led to a significant reduction of the docking step of nuclear import, as it diminished the binding of importin-α1/β1/cargo complexes at the nuclear envelope [39].

Figure 4

Mild and severe oxidative stress have different effects on nuclear transport factors. The effects of mild (2 mM DEM) and severe oxidative stress (10 mM H₂O₂) on the subcellular distribution of importin-α1, Ran, and HuR were analyzed in HeLa cells. Proteins were located by indirect immunofluorescence [39, 69, 79]. DEM treatment accumulated importin-α1 in nuclei but did not drastically affect the distribution of Ran. By contrast, severe oxidative stress induced by H₂O₂ caused a pronounced nuclear accumulation of importin-α1 and collapsed the nucleocytoplasmic Ran gradient. Both treatments relocated HuR to the cytoplasm. However, DEM triggered the assembly of HuR-containing SGs, which were rare or absent upon incubation with H₂O₂.

Our more recent studies investigated how nonlethal oxidative stress affects the transport apparatus. To this end, intracellular glutathione concentrations were depleted with DEM. Unlike severe oxidative stress, DEM incubation caused neither a dissipation of the Ran gradient (Figure 4) nor the degradation of transport receptors. However, DEM treatment mislocalized several transport components, including importin-α1, its nuclear exporter CAS as well as nucleoporins Nup153, Nup88, and Nup50 [69]. Nuclear retention was one of the mechanisms that contributed to the oxidant-induced nuclear accumulation of these proteins. Concomitant with nuclear retention, high molecular mass complexes were formed in nuclei that contained importin-α1, Nup153, and Nup88. A second mechanism promoting the redistribution of transport factors was the increase in nuclear import for importin-α1 and CAS [69]. Notably, the subcellular redistribution of importin-α1, CAS, Nup153, and Nup88 was accompanied by changes in their posttranslational modification. For example, DEM augmented the phosphorylation for each factor and increased the O-GlcNAc modification of Nup153 [117]. All of these events are possibly linked to oxidant-induced signaling, as the relocation of importin-α1, CAS, Nup153 and Nup88 was modulated by MEK → ERK1/2 and PI3K → Akt pathways [117].

Oxidative stress not only inhibits nuclear import, the Crm1 export pathway is sensitive to oxidants as well [79], and our group demonstrated that Crm1-mediated export was inhibited by DEM. Consequently, mCit-NES, a Crm1 cargo predominantly in the cytoplasm of unstressed cells, relocated to nuclei in DEM-treated samples (Figure 2). Several mechanisms participated in the oxidant-induced inhibition of Crm1-dependent export [79]. First, oxidative stress changed the association of Nup358, Nup214, Nup62, and Crm1 with the nuclear envelope and redistributed Nup98. Second, the interaction among these nucleoporins was altered. Third, oxidant treatment impaired Crm1 exit from the nucleus and increased its binding to Ran.

Taken together, these studies revealed that oxidative stress alters several steps of classical nuclear import and export and substantiated the hypothesis that the nuclear transport apparatus is an important target for oxidants. Some of the oxidant-sensitive components are shared by import and export pathways, which might explain why both transport routes are affected in stressed cells.

Work by other groups identified additional transport factors that are likely controlled by ROS homeostasis [72]. For instance, ceramide inhibited nuclear import through a pathway that relied on the MAPK p38 [123]. As ceramide is believed to cause oxidative stress [124, 125], these experiments provide another link between ROS imbalance and changes in nuclear trafficking. This idea is further supported by experiments in smooth muscle cells, where lysophosphatidylcholine modulated RanGAP1 activity [126]. Since lysophosphatidylcholine can induce ROS production [127], RanGAP1 and thereby the generation of RanGDP in the cytoplasm are potential candidates for ROS-dependent regulation. The role of RanGAP1 as an oxidant-sensitive target in the cytoplasm is significant, because RanGAP1 promotes the termination of protein export for all importin-β like carriers. Furthermore, RanGAP1 has emerged as target for several MAP kinases [128], emphasizing its potential to serve as a redox-sensitive transport regulator at the NPC.

The idea of redox-dependent control at the nuclear pore is consistent with a recent publication that detected the MAP kinases ERK, p38, and JNK at the NPC [129]. Importantly, all of these kinases are activated and/or redistributed by ROS (Table 1). Moreover Nup50, Nup153, and Nup214 are established ERK targets [130], and their phosphorylation changed several interactions that are important for nuclear transport. Specifically, ERK-dependent modification of Nup50 interfered with its binding to importin-β and transportin, which are both carriers of the importin-β family. Similarly, when Nup153 and Nup214 were phosphorylated by ERK, their association with importin-β was reduced.

In summary, multiple signaling pathways are activated by oxidants, MAP kinases reside at the NPC or relocate upon stress (see below), and several transport factors are targeted by these kinases. Hence, it is reasonable to propose a simplified chain of events: oxidative stress → signaling → transport factor modification and/or relocation → changes in nuclear trafficking → altered distribution of cargos. This is by no means a one-way street, as nuclear transport factors also play a critical role in modifying signaling events.

An example for the interdependence of signaling and nuclear transport is provided by RanBP3. This transport factor is not only regulated by multiple kinase modules, it also controls signaling [131, 132]. RanBP3 is predominantly located in the nucleus and a binding partner for Ran, RCC1, and Crm1. Aside from participating in Ran translocation to the cytoplasm, RanBP3 may also sequester Ran in the nucleus [131]. Phosphorylation by RSK and Akt can modulate RanBP3 function. In particular, RanBP3 modification is believed to stimulate nuclear import by regulating its interaction with RCC1. In support of this model, nonphosphorylatable mutants of RanBP3 displayed a reduced ability to stimulate RCC1 in vitro and caused a partial dissipation of the Ran gradient in growing cells [131]. The emerging scenario is that signaling through Ras → MEK1/2 → ERK1/2 → RSK and PI3 kinase → Akt leads to RanBP3 phosphorylation, thereby maintaining the Ran gradient. Since both signaling pathways are modulated by ROS, it is tempting to speculate that their activation by oxidants will help to preserve or re-establish the Ran gradient in stressed cells.

Besides being a downstream target of several signaling pathways, RanBP3 has a critical role in controlling TGF-β signaling [132]. Signaling through TGF-β and its receptors have multiple links to oxidative stress [133–136], and many effects of TGF-β-like ligands are exerted by the downstream transcriptional regulators Smad2/3. Smad2/3 are shuttling proteins, and their transport to the nucleus relies on direct binding to importin-β, without involvement of the adaptor importin-α [137]. Following activation of TGF-β, Smad2/3 are phosphorylated and accumulate in nuclei, where they regulate the expression of target genes. The termination of TGF-β signaling involves the dephosphorylation of Smad2/3 and their export to the cytoplasm. Notably, Smad2/3 nuclear export is not sensitive to leptomycin B, suggesting that Crm1 is not required for exit from the nucleus. Indeed, RanBP3 was identified as a possible carrier that helps to move Smad2/3 to the cytoplasm [132]. Several lines of evidence support this idea; RanBP3 bound nonphosphorylated Smad2/3, interacted with Smad2/3 in the nucleus and promoted Smad2/3 nuclear export in a Ran-dependent fashion. Together, these studies established an essential role for RanBP3 as a negative regulator of Smad2/3 signaling, which relies on its ability to transport Smad2/3 to the cytoplasm.

The impact of ROS on nuclear transport is not limited to signaling-dependent effects, since ROS can directly induce the modification of nuclear transport components. Protein carbonylation is one of the consequences of oxidative stress, and it occurs in an age-dependent fashion for nucleoporins Nup153 and Nup93. Nucleoporin carbonylation correlated with the “leakiness” of NPCs [138], and could be particularly harmful to postmitotic cells, in which some nucleoporins are replaced only slowly. In the context of signaling, it will be interesting to determine whether the age-dependent nucleoporin carbonylation alters the NPC association of MAP kinases or nucleoporin phosphorylation.

In summary, experiments described above suggest that the stress-induced modulation of nuclear trafficking is caused by changes in the concentration, distribution, and posttranslational modification of transport factors [72, 82]. This process is further complicated by the fact that oxidant-dependent relocation of transport factors can be compartmentalized even within the nucleus or cytoplasm, as shown by the formation of cytoplasmic stress granules.

2.5. Oxidative Stress, Stress Granule Assembly, and Nuclear Transport

One of the possible consequences of oxidative stress is the formation of cytoplasmic stress granules (SGs). SGs are generated in response to stress that leads to the accumulation of stalled translation initiation complexes [139, 140]. SG assembly is part of a stress defense mechanism that helps to retain and protect mRNAs from degradation. One of the signaling events crucial for the formation of most SGs is Ser51 phosphorylation on eIF2α (eukaryotic translation initiation factor 2) [139–141]. Ser51 can be modified by four different upstream kinases, PKR, PERK, GCN2, and HRI (heme-regulated initiation factor 2 kinase), which are activated by various stressors, including the oxidant arsenite. Other signaling events are relevant to SG biogenesis and disassembly; for instance, arsenite promotes the sequestration of Rho and ROCK1 in SGs, possibly to limit the activation of the downstream target JNK [142]. Moreover, focal adhesion kinase (FAK) controls the disassembly of SGs and can be stimulated with H₂O₂ [143, 144].

In addition to components of the small ribosomal subunit and RNA-binding proteins, arsenite-induced SGs contain importin-α1 [145]. Notably, importin-α1 knockdown delays SG formation, suggesting a role in the dynamics of SG assembly. These are important data which further substantiate the contribution of nuclear protein transport factors to the stress response. At present, we do not fully understand these events; however, it is conceivable that SGs are one of the “hubs”, where ROS-mediated signaling and nuclear transport components come together in the cytoplasm. Results for the mRNA-binding protein HuR support this idea. HuR shuttles between the nucleus and cytoplasm and relies on importin-α1 for nuclear import. Under normal growth conditions, HuR is predominantly in the nucleus, but a 4-hour DEM treatment concentrated HuR in SGs (Figures 3 and 4). At the same time, importin-α1 accumulated in nuclei, but it was still detectable in the cytoplasm [69, 117]. It should be emphasized that the association of macromolecules with SGs is dynamic. Proteins as well as RNA can shuttle between SGs and the surrounding cytoplasm [141, 146], and this may also apply to importin-α1.

What are the possible mechanisms that promote the ROS-dependent changes in importin-α1 and HuR distribution and how are these events linked to SG assembly? The DEM-induced relocation of HuR is likely driven by the combination of importin-α1 nuclear accumulation and HuR association with SGs. In particular, concentrating importin-α1 in nuclei of stressed cells could diminish nuclear import of HuR. At the same time, importin-α1 has a role in SG biogenesis. Although details of this process have yet to be defined, importin-α1 may recruit components to cytoplasmic foci that are destined to form SGs. Given that importin-α1 binds and transports a variety of cargos, importin-α1 shuttling between SG foci and the cytoplasm could accomplish this task. If our model is correct, it could help explain the lack of SG formation in cells incubated with H₂O₂ [147, 148]. As shown in Figure 4, H₂O₂ did not induce SGs, and importin-α1 became highly concentrated in the nucleus, with little of the protein remaining in the cytoplasm. Moreover, stress can also increase nuclear retention and import of importin-α1 [113]. As a result of these events, the concentration of importin-α1 in the cytoplasm will be low when cells are treated with H₂O₂, which in turn could limit the formation of SGs.

The potential contribution of nuclear transport factors to SG assembly or function is not restricted to importin-α1. Support for this notion comes from importin-β family members importin 8 and transportin which localize to SGs upon arsenite treatment [149, 150]. At this point, we have only few examples that connect nuclear transport components with SGs, and future studies will have to unravel how nuclear trafficking, SG assembly, and ROS-dependent signaling are integrated.

2.6. Oxidative Stress and the Subcellular Distribution of Key Signaling Molecules

Elevated levels of ROS modify the activity of redox sensitive components that participate in signaling or other essential biological processes [1, 6, 9, 39, 69, 79, 87, 88, 114, 116, 151–153]. Notably, such ROS-dependent changes in activity are frequently accompanied by the intracellular relocation of the redox-sensitive factors. This scenario applies to a growing list of protein kinases, phosphatases, transcription factors, and components of the nuclear transport apparatus (Table 1). Several of the kinases and phosphatases that redistribute under oxidative stress conditions are key players in signaling circuits, where they control cell survival, growth, proliferation, or death. The interdependence of the activation status and intracellular distribution is crucial for these enzymes, as it determines the specificity and duration of signaling events [152, 154–156]. In the following, we discuss some of the kinases and phosphatases for which oxidant-dependent relocation has been established.

The activity and location of several members of the MAPK and PI3 kinase families are modulated by ROS. Such spatiotemporal control is particularly important for the response to stress, where the repair of stress-induced damage and cell survival relies on the outcome of compartment-specific signaling events. Multiple signaling modules that respond to ROS, both by activation and relocation, have been analyzed in our group [114, 116]. We focused on Akt and ERK1/2, kinases that are essential for signal transduction through PI3 → Akt and MEK → ERK1/2 modules. The stressor DEM elevated the phosphorylation of Akt on Thr308 and Ser473, which leads to Akt activation. At the same time, DEM induced the dual phosphorylation of ERK1/2, thereby activating the MAP kinases. Importantly, DEM not only activates Akt and ERK1/2, but also increased significantly the nuclear/cytoplasmic ratio of phospho-Akt(Ser473) and dually phosphorylated-ERK1/2 [114]. A possible outcome of this shift is a change in the phosphorylation profiles of nuclear and cytoplasmic targets. Notably, the compartmentalization of Akt and ERK1/2-dependent signaling events is even more complex [114], as we demonstrated in the nucleus a direct correlation between the levels of phospho-Akt(Ser473) and phospho-ERK1/2. Our studies suggested that the nuclear concentration of phospho-Akt(Ser473) is dependent on nuclear phospho-ERK1/2 and vice versa. Accordingly, crosstalk occurs between phospho-Akt(Ser473) and ERK1/2 in response to oxidative stress; this crosstalk is specific for the nuclear compartment.

More recent work on PI3 kinase by others further emphasizes the importance of the localized action of signaling molecules. The PI3 kinase catalytic subunit p110β carries a nuclear localization signal in its C-terminal domain, while the regulatory subunit p85β harbors a nuclear export signal. The analysis of a p110β transport mutant showed that the ability of the p85β/p110β complex to regulate cell survival was strictly dependent on its nuclear localization [157]. Although the effect of oxidative stress on the distribution of this kinase has yet to be determined, these findings provide compelling evidence for the control of cell signaling by nuclear transport.

Another example that illustrates the ROS-dependent activation and distribution of protein kinases is the heterotrimeric enzyme 5′-AMP activated kinase (AMPK). AMPK is an energy sensor which plays a pivotal role in the regulation of metabolic homeostasis by phosphorylating targets that are involved in glucose, carbohydrate, lipid, and protein metabolism [158–161]. In unstressed cells, AMPK shuttles between the nucleus and cytoplasm and this shuttling relies on the nuclear exporter Crm1 [116, 162]. However, in response to oxidative stress, AMPK α- and β-subunits concentrated in the nucleus. This could be accomplished—at least in part—by ROS-induced changes to the nuclear export apparatus, as Crm1 is one of the transport components that are affected by ROS (see above). Interestingly, the link between AMPK activity, subcellular distribution, and nuclear trafficking is even more intricate, as importin-α1, a component of the nuclear transport apparatus, is also modified by AMPK [163].

Epidermal growth factor receptor (EGFR) is a receptor tyrosine kinase that is especially important to human health, because signaling through EGFR is linked to tumorigenesis, metastasis and radioresistance. EGFR is located in the plasma membrane, but it also entered the nucleus in response to oxidative stress, heat, or radiation [164]. Moreover, incubation of cultured cells with hydroxy-nonenal, a compound generated by lipid peroxidation, promoted the nuclear accumulation of EGFR [19]. When in the nucleus, EGFR stimulated DNA repair, a process that contributes to radioresistance and potentially limits the success of radiotherapy. Since EGFR is membrane bound, details of its nuclear transport are likely to differ from soluble cargos. Nevertheless, importin-β1 and Crm1 (Figure 1) were identified as nuclear carriers that participate in EGFR trafficking [165, 166].

The link between oxidative stress and the localization of key signaling components is not limited to protein kinases. For instance, the lipid and protein phosphatase PTEN has functions in the nucleus and cytoplasm, and oxidative stress promotes PTEN nuclear accumulation [167]. In cells treated with H₂O₂, PTEN concentrated in nuclei, where it stabilizes the tumor suppressor p53. Under normal conditions, PTEN is exported from the nucleus by the carrier Crm1 in a cell-cycle dependent fashion, and this export relied on signaling through PI3 kinase [168]. However, incubation with H₂O₂ induced PTEN phosphorylation on Ser380, which inhibited its nuclear export [167]. The control of PTEN shuttling upon oxidative stress probably goes beyond the oxidant-induced phosphorylation of the enzyme. As such, the exporter Crm1 is one of the cellular targets that are sensitive to ROS, and signaling through the PI3 kinase → Akt module regulates several components of the nuclear transport apparatus [79, 117]. This interdependence of nuclear transport and signaling is further complicated by the fact that the enzymatic activity of PTEN is regulated by oxidants (see below).

For the examples discussed here, ROS-mediated changes in the nucleocytoplasmic distribution of kinases and phosphatases could reflect the requirement to modify selected substrates in specific subcellular compartments. To this end, the ROS-induced nuclear accumulation of ERK1/2, PI3 kinase, AMPK, EGFR, or PTEN will alter the phosphorylation and activity of nuclear substrates such as transcription factors and other regulators of gene expression. However, such redistribution will also impact other compartments, because the sequestration of kinases or phosphatases in the nucleus can change the phosphoproteome in the cytoplasm as well.

2.7. What Is the Interface between the Initial Oxidant Exposure and Changes in the Nuclear Transport Apparatus?

As discussed in previous sections, oxidative stress targets components of the nuclear transport machinery. Moreover, different signaling cascades are implicated in the control of trafficking across the NPC, in part by regulating the posttranslational modification of nuclear transport factors. A complete mechanistic understanding of these events requires that the initial impact of the oxidant can be connected to functional changes of the nuclear transport apparatus. For many of the processes described here, the interface between the primary oxidant-induced event and changes in the posttranslational modification or function of transport factors is not fully defined. In the following, we will, therefore, speculate on some of the possible links.

In principle, two distinct mechanisms can underlie the effect of ROS on nuclear transport factors. First, ROS might react directly with the nuclear transport apparatus, leading to the covalent modification of individual components. Second, oxidative stress could activate signaling cascades that ultimately trigger the phosphorylation and/or O-GlcNAc glycosylation of the transport machinery. In the second scenario, signaling begins with a redox-sensitive target that induces a chain of events which conclude with the posttranslational modification of one or more nuclear transport factors.

Direct Modification of the Nuclear Transport Apparatus by ROS
In line with what is known about redox-sensitive residues in proteins, we expect that for nuclear transport components cysteine, methionine, lysine, arginine, and histidine residues are among the side chains that are particularly prone to direct oxidation or other ROS-dependent modifications [169]. This idea is supported by a study describing the S-nitrosylation of Crm1 on two cysteine residues and the concomitant inhibition of Crm1-mediated nuclear export [170]. Besides Crm1, nucleoporins are other candidates for a direct modification by ROS or compounds generated upon oxidative stress. Our hypothesis is supported by the increase in nucleoporin carbonylation when cells encounter oxidative stress [138].

Signaling as Possible Interface between Oxidant Exposure and Nuclear Transport Modification
Although many of the enzymes that mediate the posttranslational modification of transport factors are known, upstream events regulating these enzymes are less well understood. This applies in particular to the first step of the process, that is, the impact of ROS on its primary target. We propose that protein kinases, phosphatases, or small GTPases that are redox-sensitive [171–174] could fill this gap, as they activate signaling pathways that culminate in transport factor modification. A particularly interesting candidate in this respect is the protein kinase Src, which contains a cysteine switch that is oxidized in order to achieve full kinase activation. Moreover, the redox-dependent stimulation of Src promotes the ligand-independent transphosphorylation of EGFR and subsequent activation of PI3 and ERK kinases [175]. In line with this order of events, it is possible that the ROS-induced formation of disulfide bonds in Src will stimulate the PI3 and ERK-dependent effects on nuclear transport factors as they are discussed here.

The same reasoning applies to several phosphatases [174], including PTEN and low molecular weight protein tyrosine phosphatase (LMW-PTP). PTEN is crucial for the downregulation of PI3 kinase signaling. However, oxidant-induced thiol modification of PTEN inactivates the phosphatase, and thereby promotes signaling through the PI3 kinase → Akt module [174]. With respect to nuclear transport, ROS-induced PTEN inactivation would increase the impact of PI3 kinase on trafficking. In a similar fashion, the redox-dependent inactivation of LMW-PTP leads to sustained ERK activation [176]. This could elevate the ERK-dependent phosphorylation of soluble transport factors and nucleoporins, thus altering their function.

Aside from phosphorylation, O-GlcNAc glycosylation of nucleoporins is induced by oxidative stress. The oxidant-dependent increase in O-GlcNAc modification is possibly achieved by the complex regulation of O-GlcNAc transferase and β-N-acetylglucosaminidase. At present, these events are not fully understood [177].

Taken together, we propose that changes in the cellular redox homeostasis impact nucleocytoplasmic trafficking by two general mechanisms that are likely to operate in parallel. First, ROS or ROS-generated compounds directly modify redox-sensitive transport factors, this can alter their function. Second, the impact of ROS on redox-sensitive signaling proteins will ultimately modulate the posttranslational modification and activity of nuclear transport components.

2.8. Antioxidant Defenses Occur in a Compartmentalized Fashion

In addition to the compartmentalized activation and action of kinases and phosphatases, components of the antioxidant defense apparatus are also unequally distributed within the cell [63, 178]. This is illustrated by catalase, an enzyme concentrated in peroxisomes, and the different forms of superoxide dismutase (SOD) [64, 65, 179, 180]. While manganese-containing SOD (MnSOD) is in the mitochondrial matrix, copper- and zinc-containing SOD (Cu,ZnSOD) can be found preferentially in the cytoplasm and extracellular SOD (EC-SOD) on the cell surface. Moreover, the unequal distribution of GSH and enzymes involved in GSH metabolism will also contribute to subcellular differences in the response to ROS [59, 181–183]. Aside from these enzymes and antioxidants, the localized action of chaperones, critical factors for the repair of stress-induced damage, is well established [115, 184–186]. Since chaperone function is essential for proper signaling and also required for nuclear transport, the nucleocytoplasmic localization and function of heat shock proteins and other chaperones will have significant impact when cells experience ROS imbalances.

We propose that the unequal distribution of antioxidant defense and repair components will impact both cargos and transport factors in a compartment-specific fashion. Accordingly, the prevention and repair of oxidant-induced damage will be different in the nucleus and cytoplasm. Depending on its subcellular location, this could have differential effects on the movement and function of a shuttling protein. For example, nuclear cargos that encounter higher levels of ROS in the cytoplasm could be immobilized in this compartment. The same model can be applied to nuclear transport factors. Thus, nucleoporins on the nuclear and cytoplasmic side of the NPC could be exposed to different levels of ROS and repair. Since nuclear and cytoplasmic nucleoporins participate in different steps of trafficking, damage on either side of the nuclear pore could have unique consequences for nuclear transport.

3. Conclusions

The impact of ROS on human health is well established, and links between oxidative stress, nuclear transport, and disease have been defined. For instance, oxidative stress plays a pivotal role in the hyperglycemia-induced damage of multiple tissues and organs [47, 49, 51–53, 55, 187]. GAPDH nucleocytoplasmic shuttling not only participates in these processes, but has also been connected to cancer and neurodegenerative disorders, such as ALS, Alzheimer, or Parkinson disease [88]. Hence, it is conceivable that the oxidant-induced relocation of GAPDH is common to diabetes, cancer, and some forms of neurodegeneration. This shared feature can be extended to the stress-induced nuclear trafficking of the transcriptional regulators NF-κB and Nrf2 and may include other diseases, such as Friedreich ataxia [56, 188, 189].

The examples highlight how the compartment-specific action of signaling molecules, defense and repair reactions provide sophisticated tools to regulate cell physiology. Thus, confining these processes to specific locations will limit the access to downstream targets and clients. In the context of this review, the nucleocytoplasmic distribution of kinases, phosphatases, and other factors involved in posttranslational modification or folding can be expected to directly affect the communication between cytoplasmic and nuclear compartments. This is emphasized by the fact that many of the nuclear transport components and their cargos are modified in an ROS-dependent fashion by phosphorylation, O-GlcNAc glycosylation, acetylation, or sumoylation.

Our current understanding of ROS, signaling, and nucleocytoplasmic transport supports the notion that these processes are intricately connected. Although many of the details are still to be discovered, the findings from different fields can be merged into a simplified model. Here, we propose that crosstalk and feedback between different components of this signaling circuit will determine how cells respond to oxidative stress (Figure 5). In one scenario, the activation of signaling pathways promotes the posttranslational modification of nuclear transport factors. This triggers the redistribution of transport factors and alters the movement of cargo across the nuclear envelope. Alternatively, oxidant-induced damage to the transport apparatus could modulate the nucleocytoplasmic localization of kinases or phosphatases, thereby changing the spatiotemporal pattern of signaling. We believe that the two scenarios will take place side by side, affecting different signaling modules and targets in the nucleus and cytoplasm. Both scenarios are further shaped by the localized action of chaperones, which impact both signaling and nuclear transport. The input from signaling, trafficking, and repair will culminate in the decision on cell survival or death.

Figure 5

Simplified model for the crosstalk between signaling and nuclear transport in response to oxidative stress. Oxidative stress impinges on signaling molecules and the nuclear transport apparatus, with chaperones modulating both processes. Different scenarios can explain the communication between nuclear transport and signaling pathways in oxidant-treated cells. In one case, oxidative stress alters the localization and activity of transport factors. This will change the subcellular distribution of key signaling molecules, which in turn affects the modification of downstream targets. Alternatively, the signaling pathways activated by oxidative stress cause the modification and redistribution of transport factors. Both scenarios are likely to take place side-by-side, and the balance of these events will ultimately determine cell fate.

As outlined in this review, the dynamic organization of signaling cascades and the nuclear transport apparatus are ideal to respond to internal and external cues. In this context, nucleocytoplasmic trafficking provides the switch to direct events to the nucleus or cytoplasm. The interdependence of signaling and transport pathways provides the flexibility to adjust to a wide variety of changes in cell physiology.

Acknowledgments

This research was supported by grants from FQRNT, NSERC, and HSFQ to U. Stochaj. M. Kodiha was a recipient of a postdoctoral fellowship from McGill University.

References

D. P. Jones, “Radical-free biology of oxidative stress,” The American Journal of Physiology—Cell Physiology, vol. 295, no. 4, pp. C849–C868, 2008.
View at: Publisher Site | Google Scholar
B. Halliwell, “Role of free radicals in the neurodegenerative diseases: therapeutic implications for antioxidant treatment,” Drugs & Aging, vol. 18, no. 9, pp. 685–716, 2001.
View at: Google Scholar
D.-F. Dai and P. S. Rabinovitch, “Cardiac aging in mice and humans: the role of mitochondrial oxidative stress,” Trends in Cardiovascular Medicine, vol. 19, no. 7, pp. 213–220, 2009.
View at: Publisher Site | Google Scholar
J. Li and N. J. Holbrook, “Common mechanisms for declines in oxidative stress tolerance and proliferation with aging,” Free Radical Biology and Medicine, vol. 35, no. 3, pp. 292–299, 2003.
View at: Publisher Site | Google Scholar
T. Finkel and N. J. Holbrook, “Oxidants, oxidative stress and the biology of ageing,” Nature, vol. 408, no. 6809, pp. 239–247, 2000.
View at: Publisher Site | Google Scholar
N. J. Holbrook and S. Ikeyama, “Age-related decline in cellular response to oxidative stress: links to growth factor signaling pathways with common defects,” Biochemical Pharmacology, vol. 64, no. 5-6, pp. 999–1005, 2002.
View at: Publisher Site | Google Scholar
M. C. Haigis and B. A. Yankner, “The aging stress response,” Molecular Cell, vol. 40, no. 2, pp. 333–344, 2010.
View at: Publisher Site | Google Scholar
A. Y. Seo, A.-M. Joseph, D. Dutta, J. C. Y. Hwang, J. P. Aris, and C. Leeuwenburgh, “New insights into the role of mitochondria in aging: mitochondrial dynamics and more,” Journal of Cell Science, vol. 123, no. 15, pp. 2533–2542, 2010.
View at: Publisher Site | Google Scholar
K. C. Kregel and H. J. Zhang, “An integrated view of oxidative stress in aging: basic mechanisms, functional effects, and pathological considerations,” The American Journal of Physiology—Regulatory Integrative and Comparative Physiology, vol. 292, no. 1, pp. R18–R36, 2007.
View at: Publisher Site | Google Scholar
P. Storz, “Forkhead homeobox type O transcription factors in the responses to oxidative stress,” Antioxidants & Redox Signaling, vol. 14, no. 4, pp. 593–605, 2011.
View at: Publisher Site | Google Scholar
W. Dröge, “Free radicals in the physiological control of cell function,” Physiological Reviews, vol. 82, no. 1, pp. 47–95, 2002.
View at: Google Scholar
W. Dröge and H. M. Schipper, “Oxidative stress and aberrant signaling in aging and cognitive decline,” Aging Cell, vol. 6, no. 3, pp. 361–370, 2007.
View at: Publisher Site | Google Scholar
H.-C. Yang, M.-L. Cheng, H.-Y. Ho, and D. Tsun-Yee Chiu, “The microbicidal and cytoregulatory roles of NADPH oxidases,” Microbes and Infection, vol. 13, no. 2, pp. 109–120, 2010.
View at: Publisher Site | Google Scholar
B. M. Babior, “NADPH oxidase: an update,” Blood, vol. 93, no. 5, pp. 1464–1476, 1999.
View at: Google Scholar
M. Reth, “Hydrogen peroxide as second messenger in lymphocyte activation,” Nature Immunology, vol. 3, no. 12, pp. 1129–1134, 2002.
View at: Publisher Site | Google Scholar
M. Valko, D. Leibfritz, J. Moncol, M. T. D. Cronin, M. Mazur, and J. Telser, “Free radicals and antioxidants in normal physiological functions and human disease,” The International Journal of Biochemistry & Cell Biology, vol. 39, no. 1, pp. 44–84, 2007.
View at: Publisher Site | Google Scholar
R. Pallela, Y. Na-Young, and S.-K. Kim, “Anti-photoaging and photoprotective compounds derived from marine organisms,” Marine Drugs, vol. 8, no. 4, pp. 1189–1202, 2010.
View at: Publisher Site | Google Scholar
A. J. Ridley, J. R. Whiteside, T. J. McMillan, and S. L. Allinson, “Cellular and sub-cellular responses to UVA in relation to carcinogenesis,” International Journal of Radiation Biology, vol. 85, no. 3, pp. 177–195, 2009.
View at: Publisher Site | Google Scholar
K. Dittmann, C. Mayer, R. Kehlbach, M. C. Rothmund, and H. P. Rodemann, “Radiation-induced lipid peroxidation activates src kinase and triggers nuclear EGFR transport,” Radiotherapy & Oncology, vol. 92, no. 3, pp. 379–382, 2009.
View at: Publisher Site | Google Scholar
M. Rigoulet, E. D. Yoboue, and A. Devin, “Mitochondrial ROS generation and its regulation: mechanisms involved in H₂O₂ signaling,” Antioxidants & Redox Signaling, vol. 14, no. 3, pp. 459–468, 2011.
View at: Publisher Site | Google Scholar
K.-J. Cho, J.-M. Seo, and J.-H. Kim, “Bioactive lipoxygenase metabolites stimulation of NADPH oxidases and reactive oxygen species,” Molecules and Cells, vol. 32, no. 1, pp. 1–5, 2011.
View at: Publisher Site | Google Scholar
R. P. Brandes, N. Weissmann, and K. Schröder, “NADPH oxidases in cardiovascular disease,” Free Radical Biology & Medicine, vol. 49, no. 5, pp. 687–706, 2010.
View at: Publisher Site | Google Scholar
T. M. Paravicini and R. M. Touyz, “NADPH oxidases, reactive oxygen species, and hypertension,” Diabetes Care, vol. 31, supplement 2, pp. S170–S180, 2008.
View at: Google Scholar
F. Jiang, Y. Zhang, and G. J. Dusting, “NADPH oxidase-mediated redox signaling: roles in cellular stress response, stress tolerance, and tissue repair,” Pharmacological Reviews, vol. 63, no. 1, pp. 218–242, 2011.
View at: Publisher Site | Google Scholar
A. A. Fatokun, T. W. Stone, and R. A. Smith, “Oxidative stress in neurodegeneration and available means of protection,” Frontiers in Bioscience, vol. 13, no. 9, pp. 3288–3311, 2008.
View at: Publisher Site | Google Scholar
V. Calabrese, C. Cornelius, A. T. Dinkova-Kostova, E. J. Calabrese, and M. P. Mattson, “Cellular stress responses, the hormesis paradigm, and vitagenes: novel targets for therapeutic intervention in neurodegenerative disorders,” Antioxidants & Redox Signaling, vol. 13, no. 11, pp. 1763–1811, 2010.
View at: Publisher Site | Google Scholar
J. D. Acharya and S. S. Ghaskadbi, “Islets and their antioxidant defense,” Islets, vol. 2, no. 4, pp. 225–235, 2010.
View at: Publisher Site | Google Scholar
S. V. Avery, “Molecular targets of oxidative stress,” Biochemical Journal, vol. 434, no. 2, pp. 201–210, 2011.
View at: Publisher Site | Google Scholar
I. Dalle-Donne, A. Scaloni, D. Giustarini et al., “Proteins as biomarkers of oxidative/nitrosative stress in diseases: the contribution of redox proteomics,” Mass Spectrometry Reviews, vol. 24, no. 1, pp. 55–99, 2005.
View at: Publisher Site | Google Scholar
B. Halliwell, “Oxidative stress and neurodegeneration: where are we now?” Journal of Neurochemistry, vol. 97, no. 6, pp. 1634–1658, 2006.
View at: Publisher Site | Google Scholar
G. I. Giles and C. Jacob, “Reactive sulfur species: an emerging concept in oxidative stress,” Biological Chemistry, vol. 383, no. 3-4, pp. 375–388, 2002.
View at: Publisher Site | Google Scholar
R. P. Guttmann, “Redox regulation of cysteine-dependent enzymes,” Journal of Animal Science, vol. 88, no. 4, pp. 1297–1306, 2010.
View at: Publisher Site | Google Scholar
A. Colquhoun, “Lipids, mitochondria and cell death: implications in neuro-oncology,” Molecular Neurobiology, vol. 42, no. 1, pp. 76–88, 2010.
View at: Publisher Site | Google Scholar
L. M. Sayre, G. Perry, and M. A. Smith, “Oxidative stress and neurotoxicity,” Chemical Research in Toxicology, vol. 21, no. 1, pp. 172–188, 2008.
View at: Publisher Site | Google Scholar
M. P. Czubryt, J. A. Austria, and G. N. Pierce, “Hydrogen peroxide inhibition of nuclear protein import is mediated by the mitogen-activated protein kinase, ERK2,” The Journal of Cell Biology, vol. 148, no. 1, pp. 7–16, 2000.
View at: Publisher Site | Google Scholar
B. Halliwell, M. V. Clement, and L. H. Long, “Hydrogen peroxide in the human body,” FEBS Letters, vol. 486, no. 1, pp. 10–13, 2000.
View at: Publisher Site | Google Scholar
J. A. Imlay, “Cellular defenses against superoxide and hydrogen peroxide,” Annual Review of Biochemistry, vol. 77, no. 1, pp. 755–776, 2008.
View at: Publisher Site | Google Scholar
U. Stochaj, R. Rassadi, and J. Chiu, “Stress-mediated inhibition of the classical nuclear protein import pathway and nuclear accumulation of the small GTPase Gsp1p,” The FASEB Journal, vol. 14, no. 14, pp. 2130–2132, 2000.
View at: Google Scholar
M. Kodiha, A. Chu, N. Matusiewicz, and U. Stochaj, “Multiple mechanisms promote the inhibition of classical nuclear import upon exposure to severe oxidative stress,” Cell Death & Differentiation, vol. 11, no. 8, pp. 862–874, 2004.
View at: Publisher Site | Google Scholar
Y. Miyamoto, T. Saiwaki, J. Yamashita et al., “Cellular stresses induce the nuclear accumulation of importin α and cause a conventional nuclear import block,” The Journal of Cell Biology, vol. 165, no. 5, pp. 617–623, 2004.
View at: Publisher Site | Google Scholar
S. Boisnard, G. Lagniel, C. Garmendia-Torres et al., “H₂O₂ activates the nuclear localization of Msn2 and Maf1 through thioredoxins in Saccharomyces cerevisiae,” Eukaryotic Cell, vol. 8, no. 9, pp. 1429–1438, 2009.
View at: Publisher Site | Google Scholar
J. Song, J. Li, J. Qiao, S. Jain, B. M. Evers, and D. H. Chung, “PKD prevents H₂O₂-induced apoptosis via NF-κB and p38 MAPK in RIE-1 cells,” Biochemical and Biophysical Research Communications, vol. 378, no. 3, pp. 610–614, 2009.
View at: Publisher Site | Google Scholar
M. L. Circu and T. Y. Aw, “Reactive oxygen species, cellular redox systems, and apoptosis,” Free Radical Biology and Medicine, vol. 48, no. 6, pp. 749–762, 2010.
View at: Publisher Site | Google Scholar
S. Lenzen, “Oxidative stress: the vulnerable β-cell,” Biochemical Society Transactions, vol. 36, no. 3, pp. 343–347, 2008.
View at: Publisher Site | Google Scholar
B. van Loon, E. Markkanen, and U. Hübscher, “Oxygen as a friend and enemy: how to combat the mutational potential of 8-oxo-guanine,” DNA Repair, vol. 9, no. 6, pp. 604–616, 2010.
View at: Publisher Site | Google Scholar
B. Halliwell, “Free radicals and antioxidants—quo vadis?” Trends in Pharmacological Sciences, vol. 32, no. 3, pp. 125–130, 2011.
View at: Publisher Site | Google Scholar
J. L. Evans, I. D. Goldfine, B. A. Maddux, and G. M. Grodsky, “Oxidative stress and stress-activated signaling pathways: a unifying hypothesis of type 2 diabetes,” Endocrine Reviews, vol. 23, no. 5, pp. 599–622, 2002.
View at: Publisher Site | Google Scholar
K. Jomova, D. Vondrakova, M. Lawson, and M. Valko, “Metals, oxidative stress and neurodegenerative disorders,” Molecular and Cellular Biochemistry, vol. 345, no. 1-2, pp. 91–104, 2010.
View at: Publisher Site | Google Scholar
F. Giacco and M. Brownlee, “Oxidative stress and diabetic complications,” Circulation Research, vol. 107, no. 9, pp. 1058–1070, 2010.
View at: Publisher Site | Google Scholar
J. Ren, L. Pulakat, A. Whaley-Connell, and J. R. Sowers, “Mitochondrial biogenesis in the metabolic syndrome and cardiovascular disease,” Journal of Molecular Medicine, vol. 88, no. 10, pp. 993–1001, 2010.
View at: Publisher Site | Google Scholar
R. Stanton, “Oxidative stress and diabetic kidney disease,” Current Diabetes Reports, vol. 11, no. 4, pp. 330–336, 2011.
View at: Publisher Site | Google Scholar
C. K. Roberts and K. K. Sindhu, “Oxidative stress and metabolic syndrome,” Life Sciences, vol. 84, no. 21-22, pp. 705–712, 2009.
View at: Publisher Site | Google Scholar
S. Chrissobolis, A. A. Miller, G. R. Drummond, B. K. Kemp-Harper, and C. G. Sobey, “Oxidative stress and endothelial dysfunction in cerebrovascular disease,” Frontiers in Bioscience, vol. 16, no. 5, pp. 1733–1745, 2011.
View at: Publisher Site | Google Scholar
J. C. Jonas, M. Bensellam, J. Duprez, H. Elouil, Y. Guiot, and S. M. A. Pascal, “Glucose regulation of islet stress responses and β-cell failure in type 2 diabetes,” Diabetes, Obesity & Metabolism, vol. 11, supplement 4, pp. 65–81, 2009.
View at: Publisher Site | Google Scholar
J. L. Rains and S. K. Jain, “Oxidative stress, insulin signaling, and diabetes,” Free Radical Biology and Medicine, vol. 50, no. 5, pp. 567–575, 2011.
View at: Google Scholar
S. Reuter, S. C. Gupta, M. M. Chaturvedi, and B. B. Aggarwal, “Oxidative stress, inflammation, and cancer: how are they linked?” Free Radical Biology and Medicine, vol. 49, no. 11, pp. 1603–1616, 2010.
View at: Publisher Site | Google Scholar
Y. S. Kanwar, J. Wada, L. Sun et al., “Diabetic nephropathy: mechanisms of renal disease progression,” Experimental Biology and Medicine, vol. 233, no. 1, pp. 4–11, 2008.
View at: Publisher Site | Google Scholar
A. Tojo, K. Asaba, and M. L. Onozato, “Suppressing renal NADPH oxidase to treat diabetic nephropathy,” Expert Opinion on Therapeutic Targets, vol. 11, no. 8, pp. 1011–1018, 2007.
View at: Publisher Site | Google Scholar
P. Diaz Vivancos, T. Wolff, J. Markovic, F. V. Pallardó, and C. H. Foyer, “A nuclear glutathione cycle within the cell cycle,” Biochemical Journal, vol. 431, no. 2, pp. 169–178, 2010.
View at: Publisher Site | Google Scholar
H. R. López-Mirabal and J. R. Winther, “Redox characteristics of the eukaryotic cytosol,” Biochimica et Biophysica Acta—Molecular Cell Research, vol. 1783, no. 4, pp. 629–640, 2008.
View at: Publisher Site | Google Scholar
D. P. Jones and Y. M. Go, “Redox compartmentalization and cellular stress,” Diabetes, Obesity and Metabolism, vol. 12, no. 2, pp. 116–125, 2010.
View at: Publisher Site | Google Scholar
É. Margittai and R. Sitia, “Oxidative protein folding in the secretory pathway and redox signaling across compartments and cells,” Traffic, vol. 12, no. 1, pp. 1–8, 2011.
View at: Publisher Site | Google Scholar
O. Blokhina, E. Virolainen, and K. V. Fagerstedt, “Antioxidants, oxidative damage and oxygen deprivation stress: a review,” Annals of Botany, vol. 91, pp. 179–194, 2003.
View at: Publisher Site | Google Scholar
T. Fukai and M. Ushio-Fukai, “Superoxide dismutases: role in redox signaling, vascular function and diseases,” Antioxidants & Redox Signaling, vol. 15, no. 6, pp. 1583–1606, 2011.
View at: Google Scholar
A. Valdivia, S. Pérez-Álvarez, J. D. Aroca-Aguilar, I. Ikuta, and J. Jordán, “Superoxide dismutases: a physiopharmacological update,” Journal of Physiology & Biochemistry, vol. 65, no. 2, pp. 195–208, 2009.
View at: Publisher Site | Google Scholar
H. Jefferies, J. Coster, A. Khalil, J. Bot, R. D. McCauley, and J. C. Hall, “Glutathione,” ANZ Journal of Surgery, vol. 73, no. 7, pp. 517–522, 2003.
View at: Publisher Site | Google Scholar
N. S. Dhalla, A. B. Elmoselhi, T. Hata, and N. Makino, “Status of myocardial antioxidants in ischemia-reperfusion injury,” Cardiovascular Research, vol. 47, no. 3, pp. 446–456, 2000.
View at: Publisher Site | Google Scholar
D. M. Townsend, K. D. Tew, and H. Tapiero, “The importance of glutathione in human disease,” Biomedicine & Pharmacotherapy, vol. 57, no. 3-4, pp. 145–155, 2003.
View at: Publisher Site | Google Scholar
M. Kodiha, D. Tran, C. Qian et al., “Oxidative stress mislocalizes and retains transport factor importin-α and nucleoporins Nup153 and Nup88 in nuclei where they generate high molecular mass complexes,” Biochimica et Biophysica Acta—Molecular Cell Research, vol. 1783, no. 3, pp. 405–418, 2008.
View at: Publisher Site | Google Scholar
K. Weis, “Regulating access to the genome: nucleocytoplasmic transport throughout the cell cycle,” Cell, vol. 112, no. 4, pp. 441–451, 2003.
View at: Publisher Site | Google Scholar
S. R. Wente and M. P. Rout, “The nuclear pore complex and nuclear transport,” Cold Spring Harbor Perspectives in Biology, vol. 2, no. 10, pp. 1–19, 2010.
View at: Google Scholar
M. Kodiha, N. Crampton, S. Shrivastava, R. Umar, and U. Stochaj, “Traffic control at the nuclear pore,” Nucleus, vol. 1, no. 3, pp. 237–244, 2010.
View at: Google Scholar
I. K. H. Poon and D. A. Jans, “Regulation of nuclear transport: central role in development and transformation?” Traffic, vol. 6, no. 3, pp. 173–186, 2005.
View at: Publisher Site | Google Scholar
S. A. Adam, “The nuclear transport machinery in Caenorhabditis elegans: a central role in morphogenesis,” Seminars in Cell & Developmental Biology, vol. 20, no. 5, pp. 576–581, 2009.
View at: Publisher Site | Google Scholar
D. Adam Mason and D. S. Goldfarb, “The nuclear transport machinery as a regulator of Drosophila development,” Seminars in Cell & Developmental Biology, vol. 20, no. 5, pp. 582–589, 2009.
View at: Publisher Site | Google Scholar
S. Hutten and R. H. Kehlenbach, “CRM1-mediated nuclear export: to the pore and beyond,” Trends in Cell Biology, vol. 17, no. 4, pp. 193–201, 2007.
View at: Publisher Site | Google Scholar
N. Kudo, N. Matsumori, H. Taoka et al., “Leptomycin B inactivates CRM1/exportin 1 by covalent modification at a cysteine residue in the central conserved region,” Proceedings of the National Academy of Sciences of the United States of America, vol. 96, no. 16, pp. 9112–9117, 1999.
View at: Publisher Site | Google Scholar
D. A. Jans, C.-Y. Xiao, and M. H. C. Lam, “Nuclear targeting signal recognition: a key control point in nuclear transport?” BioEssays, vol. 22, no. 6, pp. 532–544, 2000.
View at: Publisher Site | Google Scholar
N. Crampton, M. Kodiha, S. Shrivastava, R. Umar, and U. Stochaj, “Oxidative stress inhibits nuclear protein export by multiple mechanisms that target FG nucleoporins and Crm1,” Molecular Biology of the Cell, vol. 20, no. 24, pp. 5106–5116, 2009.
View at: Publisher Site | Google Scholar
M. J. Morgan and Z. G. Liu, “Crosstalk of reactive oxygen species and NF-κB signaling,” Cell Research, vol. 21, no. 1, pp. 103–115, 2011.
View at: Publisher Site | Google Scholar
P. Ak and A. J. Levine, “p53 and NF-κB: different strategies for responding to stress lead to a functional antagonism,” The FASEB Journal, vol. 24, no. 10, pp. 3643–3652, 2010.
View at: Publisher Site | Google Scholar
V. P. Patel and C. T. Chu, “Nuclear transport, oxidative stress, and neurodegeneration,” International Journal of Clinical and Experimental Pathology, vol. 4, no. 3, pp. 215–229, 2011.
View at: Google Scholar
A. Giudice, C. Arra, and M. C. Turco, “Review of molecular mechanisms involved in the activation of the Nrf2-ARE signaling pathway by chemopreventive agents,” Methods in Molecular Biology, vol. 647, pp. 37–74, 2010.
View at: Google Scholar
A. Martín-Montalvo, J. M. Villalba, P. Navas, and R. de Cabo, “NRF2, cancer and calorie restriction,” Oncogene, vol. 30, no. 5, pp. 505–520, 2010.
View at: Publisher Site | Google Scholar
M. Theodore, Y. Kawai, J. Yang et al., “Multiple nuclear localization signals function in the nuclear import of the transcription factor Nrf2,” Journal of Biological Chemistry, vol. 283, no. 14, pp. 8984–8994, 2008.
View at: Publisher Site | Google Scholar
A. K. Jain, D. A. Bloom, and A. K. Jaiswal, “Nuclear import and export signals in control of Nrf2,” Journal of Biological Chemistry, vol. 280, no. 32, pp. 29158–29168, 2005.
View at: Publisher Site | Google Scholar
D. Tang, R. Kang, H. J. Zeh, and M. T. Lotze, “High-mobility group box 1, oxidative stress, and disease,” Antioxidants & Redox Signaling, vol. 14, no. 7, pp. 1315–1335, 2011.
View at: Publisher Site | Google Scholar
C. Tristan, N. Shahani, T. W. Sedlak, and A. Sawa, “The diverse functions of GAPDH: views from different subcellular compartments,” Cellular Signalling, vol. 23, no. 2, pp. 317–323, 2011.
View at: Publisher Site | Google Scholar
T. Bonaldi, F. Talamo, P. Scaffidi et al., “Monocytic cells hyperacetylate chromatin protein HMGB1 to redirect it towards secretion,” The EMBO Journal, vol. 22, no. 20, pp. 5551–5560, 2003.
View at: Publisher Site | Google Scholar
H. Y. Ju and J.-S. Shin, “Nucleocytoplasmic shuttling of HMGB1 is regulated by phosphorylation that redirects it toward secretion,” The Journal of Immunology, vol. 177, no. 11, pp. 7889–7897, 2006.
View at: Google Scholar
D. Tang, Y. Shi, R. Kang et al., “Hydrogen peroxide stimulates macrophages and monocytes to actively release HMGB1,” Journal of Leukocyte Biology, vol. 81, no. 3, pp. 741–747, 2007.
View at: Publisher Site | Google Scholar
K. Hayakawa, K. Arai, and E. H. Lo, “Role of ERK MAP kinase and CRM1 in IL-1β-stimulated release of HMGB1 from cortical astrocytes,” Glia, vol. 58, no. 8, pp. 1007–1015, 2010.
View at: Publisher Site | Google Scholar
D. A. Butterfield, S. S. Hardas, and M. L. B. Lange, “Oxidatively modified glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and Alzheimer's disease: many pathways to neurodegeneration,” Journal of Alzheimer's Disease, vol. 20, no. 2, pp. 369–393, 2010.
View at: Publisher Site | Google Scholar
S. Azam, N. Jouvet, A. Jilani et al., “Human glyceraldehyde-3-phosphate dehydrogenase plays a direct role in reactivating oxidized forms of the DNA repair enzyme APE1,” Journal of Biological Chemistry, vol. 283, no. 45, pp. 30632–30641, 2008.
View at: Publisher Site | Google Scholar
M. R. Hara, M. B. Cascio, and A. Sawa, “GAPDH as a sensor of NO stress,” Biochimica et Biophysica Acta, vol. 1762, no. 5, pp. 502–509, 2006.
View at: Publisher Site | Google Scholar
H. J. Kwon, J. H. Rhim, I. S. Jang, G. E. Kim, S. C. Park, and E. J. Yeo, “Activation of AMP-activated protein kinase stimulates the nuclear localization of glyceraldehyde 3-phosphate dehydrogenase in human diploid fibroblasts,” Experimental & Molecular Medicine, vol. 42, no. 4, pp. 254–269, 2010.
View at: Publisher Site | Google Scholar
S. Madsen-Bouterse, G. Mohammad, and R. A. Kowluru, “Glyceraldehyde-3-phosphate dehydrogenase in retinal microvasculature: implications for the development and progression of diabetic retinopathy,” Investigative Ophthalmology & Visual Science, vol. 51, no. 3, pp. 1765–1772, 2010.
View at: Google Scholar
H. Nakajima, W. Amano, T. Kubo et al., “Glyceraldehyde-3-phosphate dehydrogenase aggregate formation participates in oxidative stress-induced cell death,” Journal of Biological Chemistry, vol. 284, no. 49, pp. 34331–34341, 2009.
View at: Publisher Site | Google Scholar
M. A. Ortiz-Ortiz, J. M. Morán, L. M. Ruiz-Mesa, J. M. B. Pedro, and J. M. Fuentes, “Paraquat exposure induces nuclear translocation of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and the activation of the nitric oxide-GAPDH-Siah cell death cascade,” Toxicological Sciences, vol. 116, no. 2, pp. 614–622, 2010.
View at: Publisher Site | Google Scholar
J. Park, D. Han, K. Kim, Y. Kang, and Y. Kim, “O-GlcNAcylation disrupts glyceraldehyde-3-phosphate dehydrogenase homo-tetramer formation and mediates its nuclear translocation,” Biochimica et Biophysica Acta, vol. 1794, no. 2, pp. 254–262, 2009.
View at: Publisher Site | Google Scholar
M. Ventura, F. Mateo, J. Serratosa et al., “Nuclear translocation of glyceraldehyde-3-phosphate dehydrogenase is regulated by acetylation,” The International Journal of Biochemistry & Cell Biology, vol. 42, no. 10, pp. 1672–1680, 2010.
View at: Publisher Site | Google Scholar
N. E. Zachara, N. O'Donnell, W. D. Cheung, J. J. Mercer, J. D. Marth, and G. W. Hart, “Dynamic O-GlcNAc modification of nucleocytoplasmic proteins in response to stress,” Journal of Biological Chemistry, vol. 279, no. 29, pp. 30133–30142, 2004.
View at: Publisher Site | Google Scholar
A. Martínez, M. Portero-Otin, R. Pamplona, and I. Ferrer, “Protein targets of oxidative damage in human neurodegenerative diseases with abnormal protein aggregates,” Brain Pathology, vol. 20, no. 2, pp. 281–297, 2010.
View at: Publisher Site | Google Scholar
M. T. Lin and M. F. Beal, “Mitochondrial dysfunction and oxidative stress in neurodegenerative diseases,” Nature, vol. 443, no. 7113, pp. 787–795, 2006.
View at: Publisher Site | Google Scholar
J. P. Morrison, M. C. Coleman, E. S. Aunan, S. A. Walsh, D. R. Spitz, and K. C. Kregel, “Aging reduces responsiveness to BSO- and heat stress-induced perturbations of glutathione and antioxidant enzymes,” The American Journal of Physiology—Regulatory Integrative & Comparative Physiology, vol. 289, no. 4, pp. R1035–R1041, 2005.
View at: Publisher Site | Google Scholar
D. K. Singh, P. Winocour, and K. Farrington, “Oxidative stress in early diabetic nephropathy: fueling the fire,” Nature Reviews Endocrinology, vol. 7, no. 3, pp. 176–184, 2010.
View at: Publisher Site | Google Scholar
P. M. P. Balakumar, M. K. M. Arora, J. M. Reddy, and M. B. P. Anand-Srivastava, “Pathophysiology of diabetic nephropathy: involvement of multifaceted signalling mechanism,” Journal of Cardiovascular Pharmacology, vol. 54, no. 2, pp. 129–138, 2009.
View at: Publisher Site | Google Scholar
M. Brownlee, “The pathobiology of diabetic complications,” Diabetes, vol. 54, no. 6, pp. 1615–1625, 2005.
View at: Publisher Site | Google Scholar
T. Nishikawa, D. Edelstein, X. L. Du et al., “Normalizing mitochondrial superoxide production blocks three pathways of hyperglycaemic damage,” Nature, vol. 404, no. 6779, pp. 787–790, 2000.
View at: Publisher Site | Google Scholar
X. Cheng, R. C. M. Siow, and G. E. Mann, “Impaired redox signaling and antioxidant gene expression in endothelial cells in diabetes: a role for mitochondria and the nuclear factor-E2-related factor 2-Kelch-like ECH-associated protein 1 defense pathway,” Antioxidants & Redox Signaling, vol. 14, no. 3, pp. 469–487, 2011.
View at: Publisher Site | Google Scholar
M. Brownlee, “Biochemistry and molecular cell biology of diabetic complications,” Nature, vol. 414, no. 6865, pp. 813–820, 2001.
View at: Publisher Site | Google Scholar
R. G. Baker, M. S. Hayden, and S. Ghosh, “NF-κB, inflammation, and metabolic disease,” Cell Metabolism, vol. 13, no. 1, pp. 11–22, 2011.
View at: Publisher Site | Google Scholar
M. Kodiha, P. Bański, D. Ho-Wo-Cheong, and U. Stochaj, “Dissection of the molecular mechanisms that control the nuclear accumulation of transport factors importin-α and CAS in stressed cells,” Cellular & Molecular Life Sciences, vol. 65, no. 11, pp. 1756–1767, 2008.
View at: Publisher Site | Google Scholar
M. Kodiha, P. Bański, and U. Stochaj, “Interplay between MEK and PI3 kinase signaling regulates the subcellular localization of protein kinases ERK1/2 and Akt upon oxidative stress,” FEBS Letters, vol. 583, no. 12, pp. 1987–1993, 2009.
View at: Publisher Site | Google Scholar
M. Kodiha, A. Chu, O. Lazrak, and U. Stochaj, “Stress inhibits nucleocytoplasmic shuttling of heat shock protein hsc70,” The American Journal of Physiology—Cell Physiology, vol. 289, no. 4, pp. C1034–C1041, 2005.
View at: Publisher Site | Google Scholar
M. Kodiha, J. G. Rassi, C. M. Brown, and U. Stochaj, “Localization of AMP kinase is regulated by stress, cell density, and signaling through the MEK→ERK1/2 pathway,” The American Journal of Physiology—Cell Physiology, vol. 293, no. 5, pp. C1427–C1436, 2007.
View at: Publisher Site | Google Scholar
M. Kodiha, D. Tran, A. Morogan, C. Qian, and U. Stochaj, “Dissecting the signaling events that impact classical nuclear import and target nuclear transport factors,” PloS One, vol. 4, no. 12, article e8420, 2009.
View at: Google Scholar
Z. S. Chughtai, R. Rassadi, N. Matusiewicz, and U. Stochaj, “Starvation promotes nuclear accumulation of the hsp70 Ssa4p in yeast cells,” Journal of Biological Chemistry, vol. 276, no. 23, pp. 20261–20266, 2001.
View at: Publisher Site | Google Scholar
X. Quan, P. Tsoulos, A. Kuritzky, R. Zhang, and U. Stochaj, “The carrier Msn5p/Kap142p promotes nuclear export of the hsp70 Ssa4p and relocates in response to stress,” Molecular Microbiology, vol. 62, no. 2, pp. 592–609, 2006.
View at: Publisher Site | Google Scholar
X. Quan, R. Rassadi, B. Rabie, N. Matusiewicz, and U. Stochaj, “Regulated nuclear accumulation of the yeast hsp70 Ssa4p in ethanol-stressed cells is mediated by the N-terminal domain, requires the nuclear carrier Nmd5p and protein kinase C,” The FASEB Journal, vol. 18, no. 7, pp. 899–901, 2004.
View at: Google Scholar
A. Chu, N. Matusiewicz, and U. Stochaj, “Heat-induced nuclear accumulation of hsc70s is regulated by phosphorylation and inhibited in confluent cells,” The FASEB Journal, vol. 15, no. 8, pp. 1478–1480, 2001.
View at: Google Scholar
L. Sánchez, M. Kodiha, and U. Stochaj, “Monitoring the disruption of nuclear envelopes in interphase cells with GFP-beta-galactosidase,” Journal of Biomolecular Techniques, vol. 16, no. 3, pp. 235–238, 2005.
View at: Google Scholar
R. S. Faustino, P. Cheung, M. N. Richard et al., “Ceramide regulation of nuclear protein import,” Journal of Lipid Research, vol. 49, no. 3, pp. 654–662, 2008.
View at: Publisher Site | Google Scholar
X. Li, K. A. Becker, and Y. Zhang, “Ceramide in redox signaling and cardiovascular diseases,” Cellular Physiology & Biochemistry, vol. 26, no. 1, pp. 41–48, 2010.
View at: Publisher Site | Google Scholar
J.-S. Won and I. Singh, “Sphingolipid signaling and redox regulation,” Free Radical Biology & Medicine, vol. 40, no. 11, pp. 1875–1888, 2006.
View at: Publisher Site | Google Scholar
R. S. Faustino, L. N. W. Stronger, M. N. Richard et al., “RanGAP-mediated nuclear protein import in vascular smooth muscle cells is augmented by lysophosphatidylcholine,” Molecular Pharmacology, vol. 71, no. 2, pp. 438–445, 2007.
View at: Publisher Site | Google Scholar
J. W. Zmijewski, A. Landar, N. Watanabe, D. A. Dickinson, N. Noguchi, and V. M. Darley-Usmar, “Cell signalling by oxidized lipids and the role of reactive oxygen species in the endothelium,” Biochemical Society Transactions, vol. 33, no. 6, pp. 1385–1389, 2005.
View at: Publisher Site | Google Scholar
R. S. Faustino, D. C. Rousseau, M. N. Landry, A. L. Kostenuk, and G. N. Pierce, “Effects of mitogen-activated protein kinases on nuclear protein import,” Canadian Journal of Physiology & Pharmacology, vol. 84, no. 3-4, pp. 469–475, 2006.
View at: Publisher Site | Google Scholar
R. S. Faustino, T. G. Maddaford, and G. N. Pierce, “Mitogen activated protein kinase at the nuclear pore complex,” Journal of Cellular and Molecular Medicine, vol. 15, no. 4, pp. 928–937, 2011.
View at: Publisher Site | Google Scholar
H. Kosako, N. Yamaguchi, C. Aranami et al., “Phosphoproteomics reveals new ERK MAP kinase targets and links ERK to nucleoporin-mediated nuclear transport,” Nature Structural and Molecular Biology, vol. 16, no. 10, pp. 1026–1035, 2009.
View at: Publisher Site | Google Scholar
S.-O. Yoon, S. Shin, Y. Liu et al., “Ran-binding protein 3 phosphorylation links the Ras and PI3-kinase pathways to nucleocytoplasmic transport,” Molecular Cell, vol. 29, no. 3, pp. 362–375, 2008.
View at: Publisher Site | Google Scholar
F. Dai, X. Lin, C. Chang, and X.-H. Feng, “Nuclear export of Smad2 and Smad3 by RanBP3 facilitates termination of TGF-beta signaling,” Developmental Cell, vol. 16, no. 3, pp. 345–357, 2009.
View at: Publisher Site | Google Scholar
K. Koli, M. Myllärniemi, J. Keski-Oja, and V. L. Kinnula, “Transforming growth factor-β activation in the lung: focus on fibrosis and reactive oxygen species,” Antioxidants & Redox Signaling, vol. 10, no. 2, pp. 333–342, 2008.
View at: Publisher Site | Google Scholar
X. Z. Shi, J. H. Winston, and S. K. Sarna, “Differential immune and genetic responses in rat models of Crohn's colitis and ulcerative colitis,” The American Journal of Physiology—Gastrointestinal & Liver Physiology, vol. 300, no. 1, pp. G41–G51, 2011.
View at: Publisher Site | Google Scholar
H. Sone, H. Akanuma, and T. Fukuda, “Oxygenomics in environmental stress,” Redox Report, vol. 15, no. 3, pp. 98–114, 2010.
View at: Publisher Site | Google Scholar
G. H. Tesch and A. K. Lim, “Recent insights into diabetic renal injury from the db/db mouse model of type 2 diabetic nephropathy,” The American Journal of Physiology—Renal Physiology, vol. 300, no. 2, pp. F301–F310, 2011.
View at: Publisher Site | Google Scholar
C. S. Hill, “Nucleocytoplasmic shuttling of Smad proteins,” Cell Research, vol. 19, no. 1, pp. 36–46, 2009.
View at: Google Scholar
M. A. D'Angelo, M. Raices, S. H. Panowski, and M. W. Hetzer, “Age-dependent deterioration of nuclear pore complexes causes a loss of nuclear integrity in postmitotic cells,” Cell, vol. 136, no. 2, pp. 284–295, 2009.
View at: Publisher Site | Google Scholar
P. Anderson and N. Kedersha, “Stress granules: the Tao of RNA triage,” Trends in Biochemical Sciences, vol. 33, no. 3, pp. 141–150, 2008.
View at: Publisher Site | Google Scholar
M. G. Thomas, M. Loschi, M. A. Desbats, and G. L. Boccaccio, “RNA granules: the good, the bad and the ugly,” Cellular Signalling, vol. 23, no. 2, pp. 324–334, 2011.
View at: Publisher Site | Google Scholar
J. R. Buchan and R. Parker, “Eukaryotic stress granules: the ins and outs of translation,” Molecular Cell, vol. 36, no. 6, pp. 932–941, 2009.
View at: Publisher Site | Google Scholar
N.-P. Tsai and L.-N. Wei, “RhoA/ROCK1 signaling regulates stress granule formation and apoptosis,” Cellular Signalling, vol. 22, no. 4, pp. 668–675, 2010.
View at: Publisher Site | Google Scholar
N.-P. Tsai, P.-C. Ho, and L.-N. Wei, “Regulation of stress granule dynamics by Grb7 and FAK signalling pathway,” The EMBO Journal, vol. 27, no. 5, pp. 715–726, 2008.
View at: Publisher Site | Google Scholar
S. Basuroy, M. Dunagan, P. Sheth, A. Seth, and R. K. Rao, “Hydrogen peroxide activates focal adhesion kinase and c-Src by a phosphatidylinositol 3 kinase-dependent mechanism and promotes cell migration in Caco-2 cell monolayers,” The American Journal of Physiology—Gastrointestinal & Liver Physiology, vol. 299, no. 1, pp. G186–G195, 2010.
View at: Publisher Site | Google Scholar
K. Fujimura, T. Suzuki, Y. Yasuda, M. Murata, J. Katahira, and Y. Yoneda, “Identification of importin α1 as a novel constituent of RNA stress granules,” Biochimica et Biophysica Acta—Molecular Cell Research, vol. 1803, no. 7, pp. 865–871, 2010.
View at: Publisher Site | Google Scholar
S. Mollet, N. Cougot, A. Wilczynska et al., “Translationally repressed mRNA transiently cycles through stress granules during stress,” Molecular Biology of the Cell, vol. 19, no. 10, pp. 4469–4479, 2008.
View at: Publisher Site | Google Scholar
W. J. Kim, S. H. Back, V. Kim, I. Ryu, and S. K. Jang, “Sequestration of TRAF2 into stress granules interrupts tumor necrosis factor signaling under stress conditions,” Molecular and Cellular Biology, vol. 25, no. 6, pp. 2450–2462, 2005.
View at: Publisher Site | Google Scholar
N. Kedersha and P. Anderson, “Mammalian stress granules and processing bodies,” Methods in Enzymology, vol. 431, pp. 61–81, 2007.
View at: Publisher Site | Google Scholar
L. Weinmann, J. Höck, T. Ivacevic et al., “Importin 8 is a gene silencing factor that targets argonaute proteins to distinct mRNAs,” Cell, vol. 136, no. 3, pp. 496–507, 2009.
View at: Publisher Site | Google Scholar
W.-L. Chang and W.-Y. Tarn, “A role for transportin in deposition of TTP to cytoplasmic RNA granules and mRNA decay,” Nucleic Acids Research, vol. 37, no. 19, pp. 6600–6612, 2009.
View at: Publisher Site | Google Scholar
M. Ito, K. Miyado, K. Nakagawa et al., “Age-associated changes in the subcellular localization of phosphorylated p38 MAPK in human granulosa cells,” Molecular Human Reproduction, vol. 16, no. 12, pp. 928–937, 2010.
View at: Publisher Site | Google Scholar
N. R. Leslie, “The redox regulation of PI 3-kinase-dependent signaling,” Antioxidants & Redox Signaling, vol. 8, no. 9-10, pp. 1765–1774, 2006.
View at: Publisher Site | Google Scholar
P. Storz, “Reactive oxygen species-mediated mitochondria-to-nucleus signaling: a key to aging and radical-caused diseases,” Science's STKE, vol. 2006, no. 332, p. re3, 2006.
View at: Publisher Site | Google Scholar
J.-F. L. Bodart, “Extracellular-regulated kinase—mitogen-activated protein kinase cascade: unsolved issues,” Journal of Cellular Biochemistry, vol. 109, no. 5, pp. 850–857, 2010.
View at: Publisher Site | Google Scholar
L. T. May and S. J. Hill, “ERK phosphorylation: spatial and temporal regulation by G protein-coupled receptors,” The International Journal of Biochemistry & Cell Biology, vol. 40, no. 10, pp. 2013–2017, 2008.
View at: Publisher Site | Google Scholar
B. Ananthanarayanan, Q. Ni, and J. Zhang, “Signal propagation from membrane messagers to nuclear effectors revealed by reporters of phosphoinositide dynamics and Akt activity,” Proceedings of the National Academy of Sciences of the United States of America, vol. 102, no. 42, pp. 15081–15086, 2005.
View at: Publisher Site | Google Scholar
A. Kumar, J. Redondo-Muñoz, V. Perez-García, I. Cortes, M. Chagoyen, and A. C. Carrera, “Nuclear but not cytosolic phosphoinositide 3-kinase beta has an essential function in cell survival,” Molecular and Cellular Biology, vol. 31, no. 10, pp. 2122–2133, 2011.
View at: Publisher Site | Google Scholar
M. Kodiha and U. Stochaj, “Targeting AMPK for therapeutic intervention in type 2 diabetes,” in Medical Complications of Type 2 Diabetes, C. Croniger, Ed., InTech, 2011, http://www.intechopen.com/articles/show/title/targeting-ampk-for-therapeutic-intervention-in-type-2-diabetes.
View at: Google Scholar
D. G. Hardie, “AMPK: a key regulator of energy balance in the single cell and the whole organism,” International Journal of Obesity, vol. 32, supplement 4, pp. S7–S12, 2008.
View at: Publisher Site | Google Scholar
G. R. Steinberg and B. E. Kemp, “AMPK in health and disease,” Physiological Reviews, vol. 89, no. 3, pp. 1025–1078, 2009.
View at: Publisher Site | Google Scholar
B. Viollet, S. Horman, J. Leclerc et al., “AMPK inhibition in health and disease,” Critical Reviews in Biochemistry & Molecular Biology, vol. 45, no. 4, pp. 276–295, 2010.
View at: Publisher Site | Google Scholar
N. Kazgan, T. Williams, L. J. Forsberg, and J. E. Brenman, “Identification of a nuclear export signal in the catalytic subunit of AMP-activated protein kinase,” Molecular Biology of the Cell, vol. 21, no. 19, pp. 3433–3442, 2010.
View at: Publisher Site | Google Scholar
W. Wang, X. Yang, T. Kawai et al., “AMP-activated protein kinase-regulated phosphorylation and acetylation of importin α1: involvement in the nuclear import of RNA-binding protein HuR,” Journal of Biological Chemistry, vol. 279, no. 46, pp. 48376–48388, 2004.
View at: Publisher Site | Google Scholar
H. W. Lo and M. C. Hung, “Nuclear EGFR signalling network in cancers: linking EGFR pathway to cell cycle progression, nitric oxide pathway and patient survival,” The British Journal of Cancer, vol. 94, no. 2, pp. 184–188, 2006.
View at: Publisher Site | Google Scholar
Y.-N. Wang, H. Yamaguchi, L. Huo et al., “The translocon Sec61β localized in the inner nuclear membrane transports membrane-embedded EGF receptor to the nucleus,” Journal of Biological Chemistry, vol. 285, no. 49, pp. 38720–38729, 2010.
View at: Publisher Site | Google Scholar
H.-W. Lo, M. Ali-Seyed, Y. Wu, G. Bartholomeusz, S. C. Hsu, and M. C. Hung, “Nuclear-cytoplasmic transport of EGFR involves receptor endocytosis, importin β1 and CRM1,” Journal of Cellular Biochemistry, vol. 98, no. 6, pp. 1570–1583, 2006.
View at: Publisher Site | Google Scholar
C.-J. Chang, D. J. Mulholland, B. Valamehr, S. Mosessian, W. R. Sellers, and H. Wu, “PTEN nuclear localization is regulated by oxidative stress and mediates p53-dependent tumor suppression,” Molecular and Cellular Biology, vol. 28, no. 10, pp. 3281–3289, 2008.
View at: Publisher Site | Google Scholar
J.-L. Liu, Z. Mao, T. A. LaFortune et al., “Cell cycle-dependent nuclear export of phosphatase and tensin homologue tumor suppressor is regulated by the phosphoinositide-3-kinase signaling cascade,” Cancer Research, vol. 67, no. 22, pp. 11054–11063, 2007.
View at: Publisher Site | Google Scholar
I. Dalle-Donne, G. Aldini, M. Carini, R. Colombo, R. Rossi, and A. Milzani, “Protein carbonylation, cellular dysfunction, and disease progression,” Journal of Cellular and Molecular Medicine, vol. 10, no. 2, pp. 389–406, 2006.
View at: Publisher Site | Google Scholar
P. Wang, G.-H. Liu, K. Wu et al., “Repression of classical nuclear export by S-nitrosylation of CRM1,” Journal of Cell Science, vol. 122, no. 20, pp. 3772–3779, 2009.
View at: Publisher Site | Google Scholar
E. Giannoni, M. L. Taddei, and P. Chiarugi, “Src redox regulation: again in the front line,” Free Radical Biology and Medicine, vol. 49, no. 4, pp. 516–527, 2010.
View at: Publisher Site | Google Scholar
T. Adachi, D. R. Pimentel, T. Heibeck et al., “S-glutathiolation of Ras mediates redox-sensitive signaling by angiotensin II in vascular smooth muscle cells,” Journal of Biological Chemistry, vol. 279, no. 28, pp. 29857–29862, 2004.
View at: Publisher Site | Google Scholar
A. Aghajanian, E. S. Wittchen, S. L. Campbell, and K. Burridge, “Direct activation of RhoA by reactive oxygen species requires a redox-sensitive motif,” PloS One, vol. 4, no. 11, article e8045, 2009.
View at: Google Scholar
N. Brandes, S. Schmitt, and U. Jakob, “Thiol-based redox switches in eukaryotic proteins,” Antioxidants & Redox Signaling, vol. 11, no. 5, pp. 997–1014, 2009.
View at: Publisher Site | Google Scholar
E. Giannoni, F. Buricchi, G. Grimaldi et al., “Redox regulation of anoikis: reactive oxygen species as essential mediators of cell survival,” Cell Death & Differentiation, vol. 15, no. 5, pp. 867–878, 2008.
View at: Publisher Site | Google Scholar
E. Giannoni, G. Raugei, P. Chiarugi, and G. Ramponi, “A novel redox-based switch: LMW-PTP oxidation enhances Grb2 binding and leads to ERK activation,” Biochemical & Biophysical Research Communications, vol. 348, no. 2, pp. 367–373, 2006.
View at: Publisher Site | Google Scholar
C. Butkinaree, K. Park, and G. W. Hart, “O-linked β-N-acetylglucosamine (O-GlcNAc): extensive crosstalk with phosphorylation to regulate signaling and transcription in response to nutrients and stress,” Biochimica et Biophysica Acta—General Subjects, vol. 1800, no. 2, pp. 96–106, 2010.
View at: Publisher Site | Google Scholar
R. M. Green, M. Graham, M. R. O'Donovan, J. K. Chipman, and N. J. Hodges, “Subcellular compartmentalization of glutathione: correlations with parameters of oxidative stress related to genotoxicity,” Mutagenesis, vol. 21, no. 6, pp. 383–390, 2006.
View at: Publisher Site | Google Scholar
F. Johnson and C. Giulivi, “Superoxide dismutases and their impact upon human health,” Molecular Aspects of Medicine, vol. 26, no. 4-5, pp. 340–352, 2005.
View at: Publisher Site | Google Scholar
M. Schrader and H. D. Fahimi, “Peroxisomes and oxidative stress,” Biochimica et Biophysica Acta—Molecular Cell Research, vol. 1763, no. 12, pp. 1755–1766, 2006.
View at: Publisher Site | Google Scholar
P. D. Vivancos, Y. Dong, K. Ziegler et al., “Recruitment of glutathione into the nucleus during cell proliferation adjusts whole-cell redox homeostasis in Arabidopsis thaliana and lowers the oxidative defence shield,” The Plant Journal, vol. 64, no. 5, pp. 825–838, 2010.
View at: Publisher Site | Google Scholar
J. Markovic, N. J. Mora, A. M. Broseta et al., “The depletion of nuclear glutathione impairs cell proliferation in 3t3 fibroblasts,” PLoS One, vol. 4, no. 7, article e6413, 2009.
View at: Publisher Site | Google Scholar
K. Kamada, S. Goto, T. Okunaga et al., “Nuclear glutathione S-transferase π prevents apoptosis by reducing the oxidative stress-induced formation of exocyclic DNA products,” Free Radical Biology & Medicine, vol. 37, no. 11, pp. 1875–1884, 2004.
View at: Publisher Site | Google Scholar
J. C. Young, J. M. Barral, and F. U. Hartl, “More than folding: localized functions of cytosolic chaperones,” Trends in Biochemical Sciences, vol. 28, no. 10, pp. 541–547, 2003.
View at: Publisher Site | Google Scholar
P. Bański, M. Kodiha, and U. Stochaj, “Chaperones and multitasking proteins in the nucleolus: networking together for survival?” Trends in Biochemical Sciences, vol. 35, no. 7, pp. 361–367, 2010.
View at: Publisher Site | Google Scholar
P. Bański, M. Kodiha, and U. Stochaj, “Exploring the nuclear proteome: novel concepts for chaperone trafficking and function,” Current Proteomics, vol. 8, no. 1, pp. 59–82, 2011.
View at: Publisher Site | Google Scholar
O. Huet, L. Dupic, A. Harrois, and J. Duranteau, “Oxidative stress and endothelial dysfunction during sepsis,” Frontiers in Bioscience, vol. 16, no. 5, pp. 1986–1995, 2011.
View at: Publisher Site | Google Scholar
J. Pi, Q. Zhang, J. Fu et al., “ROS signaling, oxidative stress and Nrf2 in pancreatic beta-cell function,” Toxicology and Applied Pharmacology, vol. 244, no. 1, pp. 77–83, 2010.
View at: Publisher Site | Google Scholar
V. Paupe, E. P. Dassa, S. Goncalves et al., “Impaired nuclear Nrf2 translocation undermines the oxidative stress response in Friedreich ataxia,” PLoS One, vol. 4, no. 1, article e4253, 2009.
View at: Publisher Site | Google Scholar

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Copyright © 2012 Mohamed Kodiha and Ursula Stochaj. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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