Redox Biology

Ras proteins are membrane-bound GTPases that regulate essential cellular processes at the plasma membrane (PM). Constitutively active mutations of K-Ras, one of the three Ras isoforms in mammalian cells, are frequently found in human cancers. Ferrocene derivatives, which elevate cellular reactive oxygen species (ROS), have shown to block the growth of non-small cell lung cancers (NSCLCs) harboring oncogenic mutant K-Ras. Here, we developed and tested a novel ferrocene derivative on the growth of human pancreatic ductal adenocarcinoma (PDAC) and NSCLC. Our compound inhibited the growth of K-Ras-dependent PDAC and NSCLC and abrogated the PM binding and signaling of K-Ras, but not other Ras isoforms. These effects were reversed upon antioxidant supplementation, suggesting a ROS-mediated mechanism. We further identified K-Ras His95 residue in the G-domain as being involved in the ferrocene-induced K-Ras PM dissociation via oxidative modification. Together, our studies demonstrate that the redox system directly regulates K-Ras PM binding and signaling via oxidative modification at the His95, and proposes a role of oncogenic mutant K-Ras in the recently described antioxidant-induced metastasis in K-Ras-driven lung cancers.

Single molecule mass photometry was used to study the dynamic equilibria of the ubiquitous and highly abundant 2-Cysteine peroxiredoxins (2-CysPRX). 2-CysPRXs adopt distinct functions in all cells dependent on their oligomeric conformation ranging from dimers to decamers and high molecular weight aggregates (HMW). The oligomeric state depends on the redox state of their catalytic cysteinyl residues. To which degree they interconvert, how the interconversion is regulated, and how the oligomerisation propensity is organism specific remains, however, poorly understood. The dynamics differs between wild-type and single point mutants affecting the oligomerization interfaces, with concomitant changes to function. Titrating concentration and redox state of Arabidopsis thaliana and human 2-CysPRXs revealed features conserved among all 2-CysPRX and clear differences concerning oligomer transitions, the occurrence of transition states and the formation of HMW which are associated with chaperone activity or storage. The results indicate functional differentiation of human 2-CysPRXs. Our results point to a diversified functionality of oligomerization for 2-CysPRXs and illustrate the power of mass photometry to non-invasively quantify oligomer distributions in a redox environment. This knowledge is important to fully address and model PRX function in cell redox signaling e.g., in photosynthesis, cardiovascular and neurological diseases or carcinogenesis.

Glutathione is the major thiol-based antioxidant in a wide variety of biological systems, ranging from bacteria to eukaryotes. As a redox couple, consisting of reduced glutathione (GSH) and oxidized glutathione disulfide (GSSG), it is crucial for the maintenance of the cellular redox balance. Glutathione transport out of and into cellular compartments and the extracellular space is a determinant of the thiol-disulfide redox state of the organelles and bodily fluids in question, but is currently not well understood. Here we use the genetically-encoded, glutathione-measuring redox probe Grx1-roGFP2 to comprehensively elucidate the import of extracellular glutathione into the cytoplasm of the model organism Escherichia coli. The elimination of only two ATP-Binding Cassette (ABC) transporter systems, Gsi and Opp, completely abrogates glutathione import into E. colis cytoplasm, both in its reduced and oxidized form. The lack of only one of them, Gsi, completely prevents import of oxidized glutathione (GSSG), while the lack of the other, Opp, substantially retards the uptake of reduced glutathione (GSH).

Partial reduction of oxygen during energy generating metabolic processes in aerobic life forms results in the production of reactive oxygen species (ROS). In plants, ROS production is heightened during periods of both abiotic and biotic stress, which imposes a significant overload on the antioxidant systems. Hydrogen peroxide (H2O2) holds a central position in cellular redox homeostasis and signalling, playing an important role by oxidising crucial cysteines to sulfenic acid (-SOH), considered as a biologically relevant post-translational modification (PTM). Until now, the role of the nucleus in the cellular redox homeostasis has been relatively underexplored. The regulation of histone-modifying enzymes by oxidative PTMs on redox-active cysteines or tyrosine residues is particularly intriguing as it allows the integration of redox signalling mechanisms with chromatin control of transcriptional activity. One of the most extensively studied histone acetyltransferases is the conserved GENERAL CONTROL NONDEPRESSIBLE 5 (GCN5) complex. This study investigated the nuclear sulfenome in Arabidopsis thaliana by expressing a nuclear variant of the Yeast Activation Protein-1 (YAP) probe, identifying 225 potential redox-active nuclear proteins subject to sulfenylation. Mass spectrometry analysis further confirmed the sulfenylation of GCN5 at specific cysteine residues, with their functional significance and impact on the protein-protein interaction network assessed through cysteine-to-serine mutagenesis. HighlightProtein cysteine thiols are post-translationally modified under oxidative stress. Through the in vivo capturing of nuclear proteins undergoing sulfenylation in Arabidopsis, we highlight the functionality of particular cysteines in the histone acetyltransferase GCN5.

YbbN/CnoX are proteins that display a Trx domain linked to a tetratricopeptide (TPR) domain, which are involved in protein-protein interactions and protein folding processes. YbbN from Escherichia coli (EcYbbN) displays a co-chaperone (holdase) activity that is induced by HOCl (bleach). EcYbbN contains a SQHC motif within the Trx domain and displays no thiol-disulfide oxidoreductase activity. EcYbbN also presents a second Cys residue at Trx domain (Cys63) 24 residues away from SQHF motif that can form mixed disulfides with substrates. Here, we compared EcYbbN with two other YbbN proteins: from Xylella fastidiosa (XfYbbN) and from Pseudomonas aeruginosa (PaYbbN). While EcYbbN displays two Cys residues along a SQHC[N24]C motif; XfYbbN and PaYbbN present two and three Cys residues in the CAPC[N24]V and CAPC[N24]C motifs, respectively. These three proteins are representatives of evolutionary conserved YbbN subfamilies. In contrast to EcYbbN, both XfYbbN and PaYbbN: (1) reduced an artificial disulfide (5,5'-dithiobis-(2-nitrobenzoic acid) = DTNB); and (2) supported the peroxidase activity of Peroxiredoxin Q from X. fastidiosa, suggesting that in vivo these proteins might function similarly to the canonical Trx enzymes. Indeed, XfYbbN was reduced by XfTrx reductase with a high catalytic efficiency (kcat/Km=1.27 x 107 M-1.s-1), like the canonical XfTrx (XfTsnC). Furthermore, EcYbbN (as described before) and XfYbbN, but not PaYbbN displayed HOCl-induced holdase activity. Remarkably, EcYbbN gained disulfide reductase activity while lost the HOCl-activated chaperone function when the SQHC was replaced by CQHC. In contrast, the XfYbbN C40A mutant lost the disulfide reductase activity, while kept its HOCl-induced chaperone function. Finally, we generated a P. aeruginosa strain with the ybbN gene deleted, which did not present increased sensitivity to heat shock or to oxidants or to reductants. Altogether, our results suggest that different YbbN/CnoX proteins display distinct properties and activities, depending on the presence of the three conserved Cys residues. Graphical Abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=91 SRC="FIGDIR/small/034579v1_ufig1.gif" ALT="Figure 1"> View larger version (11K): org.highwire.dtl.DTLVardef@6970f0org.highwire.dtl.DTLVardef@75da52org.highwire.dtl.DTLVardef@15067c9org.highwire.dtl.DTLVardef@1cdd97d_HPS_FORMAT_FIGEXP M_FIG C_FIG Highlights- CXXC motif is required for the thiol-disulfide reductase activity of YbbN proteins. - XfYbbN and PaYbbN display thiol-disulfide oxidoreductase activity - The affinities of XfTrxR for XfYbbN and XfTsnC (canonical Trx) are comparable - XfYbbN and EcYbbN, but not PaYbbN, display holdase activity induced by hypochlorous acid - Engineering EcYbbN/CnoX by inserting a Cys residue in the SQHC motif resulted in a gain of function (thiol-disulfide oxidoreductase activity) and abolished the HOCl-induced holdase activity.

In the mammalian endoplasmic reticulum (ER), the diverse network comprising more than 20 members of the protein disulfide isomerase (PDI) family and more than five PDI oxidases has evolved to promote oxidative protein folding. While the canonical disulfide bond formation pathway constituted by Ero1 and PDI has been well studied so far, mechanistic and physiological bases of newly identified PDI oxidases, glutathione peroxidase-7 (GPx7) and -8 (GPx8), are only poorly understood. We here demonstrated that human GPx7 has much higher reactivity with H2O2 than human GPx8, leading to efficient PDI oxidation. GPx7 forms a catalytic tetrad at the redox active site to react with H2O2 efficiently and stabilize a resultantly generated sulfenylated species. While it was previously postulated that the GPx7 catalysis involved a highly reactive peroxidatic cysteine, a resolving cysteine was found to act to regulate the PDI oxidation activity of GPx7. The present study also revealed that GPx7 formed complexes preferentially with PDI and P5 in H2O2-treated cells. Altogether, human GPx7 functions as an H2O2-dependent PDI oxidase in cells whereas PDI oxidation may not be the central physiological role of human GPx8.

Glutathione (GSH) is essential for cellular redox regulation; however, the redox potential (EGSH) of the nucleus and membraneless organelles (MLOs) remains poorly understood. Here, we use the Grx1-roGFP2 sensor to measure the EGSH of the nucleus and several MLOs such as the nucleoli, stress granules, p-bodies, paraspeckles, and Cajal bodies. Unlike suggested by previous findings, we found that nuclear EGSH is stable throughout the cell cycle and identical to the cytosolic EGSH, and the EGSH of MLOs mirrors their surrounding environment. These findings challenge existing paradigms and provide novel insights into redox homeostasis across subcellular compartments.

T lymphocytes are key components in adaptive immunity and their activation naturally involves mitochondrial-derived oxygen species (mtROS). In particular, H2O2 has been implicated as an important signaling molecule regulating major T cell functions. H2O2 targets the oxidation status of functional cysteine residues but knowledge if and where this happens in T cell signaling networks is widely missing. This study aimed to identify mtROS-sensitive processes in activated primary human CD4+ T cells. By using a thiol-specific redox proteomic approach we examined the oxidation state of 4784 cysteine-containing peptides of ex vivo stimulated T cells from healthy individuals. Upon activation, a shift in oxidation was observed at catalytic cysteine residues of peroxiredoxins (PRDX5 & PRDX6), and T cells were found to maintain their global thiol-redox homeostasis. In parallel, a distinct set of 88 cysteine residues were found to be differentially oxidized upon T cell activation suggesting novel functional thiol switches. In mitochondria, cysteine oxidations selectively modified regulators of respiration (NDUFA2, NDUFA8, and UQCRH) confirming electron leakage from electron transport complexes I and III. The majority of oxidations occurred outside mitochondria and enriched sensitive thiols at regulators of cytoskeleton dynamics (e.g. CYFIP2 and ARPC1B) and known immune functions including the non-receptor tyrosine phosphatase PTPN7. Conversely, cysteine reduction occurred predominantly at transcriptional regulators and sites that coordinate zinc-binding in zinc-finger motifs. Indeed, fluorescence microscopy revealed a colocalization of zinc-rich microenvironments and mitochondria in T cells suggesting mtROS-dependent zinc-release of identified transcriptional regulators including ZFP36, RPL37A and CRIP2. In conclusion, this study complements knowledge on the mtROS signaling network and suggests zinc-dependent thiol switches as a mechanism of how mtROS affects transcription and translation in T cells.

RAP guanine exchange factors (RAPGEF3/4) also known as EPAC1/2 (Exchange Protein Activated by cyclic AMP) are important signaling proteins. In cutaneous melanoma, we reported that loss of dependency on RAPGEF3/4 is associated with metastatic progression. Here, we investigated the molecular mechanisms underlying EPAC1/2 signaling in melanoma. Using transformed human melanocytes, chemical inhibition and genetic deletion of EPAC in Braf/Pten mice, we show that EPAC activation is an early event in melanomagenesis and is required for the growth of transformed melanocytes in vitro and melanomagenesis in vivo. Query of the Cancer Genome Atlas (TCGA) and immunohistochemical analysis of melanoma tumors showed that low EPAC mRNA and RAP1-GTP protein correlate with better diseases free survival of patients with primary melanoma. RNAseq analysis of patient-matched primary and metastatic melanoma cells treated with EPAC inhibitor ESI-09 revealed that TXNIP, an important regulator of redox homeostasis, is a downstream effector of EPAC-RAP1 signaling. Our data also show that EPACs promote melanoma growth by regulation of redox homeostasis and mitochondrial reactive oxygen species through activation of mechanistic target of rapamycin complex 1 (mTORC1) that stabilizes hypoxia-inducible factor 1-alpha (HIF-1), a transcriptional activator of TXNIP and glycolytic enzymes. Our data suggest that targeting mechanisms that metastatic melanoma cells employ to bypass EPAC dependency as a potential therapeutic approach for melanoma. Graphical Abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=134 SRC="FIGDIR/small/696903v1_ufig1.gif" ALT="Figure 1"> View larger version (30K): org.highwire.dtl.DTLVardef@1b0bc1eorg.highwire.dtl.DTLVardef@e8499org.highwire.dtl.DTLVardef@1237175org.highwire.dtl.DTLVardef@1edbd02_HPS_FORMAT_FIGEXP M_FIG C_FIG

Chronic obstructive pulmonary disease (COPD) is characterized by neutrophilic inflammation, emphysema, and mild pulmonary hypertension (PH). Oxidative/nitrosative stress are key drivers, but specific mitochondrial mechanisms remain unclear. We show increased expression of the regulatory mitochondrial cytochrome c oxidase subunit 4 isoform 2 (COX4I2) in an early murine model and human COPD. After 8 months of cigarette smoke exposure, Cox4i2-/- mice were completely protected from emphysema but not from PH, associated with reduced nitrosative stress, inflammation, and apoptosis. Using a novel Cox4i2 reporter mouse and in situ hybridization of human lungs, COX4I2 was detected in precapillary ACTA2+ cells and capillary pericytes. COX4I2 promotes mitochondrial reactive oxygen species (mtROS) production in these cells, thereby enhancing neutrophil migration and alveolar type II cell apoptosis, and modulates angiogenesis. In contrast to Cox4i2-/-, mitochondria-targeted antioxidant MitoQ reversed emphysema and PH, suggesting pericyte-specific regulation of COPD pathologies and mtROS inhibition as a therapeutic approach in COPD. Graphical abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=124 SRC="FIGDIR/small/703513v1_ufig1.gif" ALT="Figure 1"> View larger version (39K): org.highwire.dtl.DTLVardef@83bca4org.highwire.dtl.DTLVardef@d5ebaborg.highwire.dtl.DTLVardef@632d1borg.highwire.dtl.DTLVardef@1267a13_HPS_FORMAT_FIGEXP M_FIG C_FIG

The Keap1-Nrf2 signalling to transcriptionally regulate antioxidant response element (ARE)-driven target genes has been accepted as key redox-sensitive pathway governing a vast variety of cellular stresses during healthy survival and disease development. Herein, we identified two nuanced isoforms and {beta} of Keap1, arising from its first and another in-frame translation starting codons, respectively. In identifying those differential expression genes monitored by Keap1 and/or Keap1{beta}, an unusual interaction of Keap1 with Smad2/3 was discovered by parsing transcriptome sequencing, Keap1-interacting protein profiling and relevant immunoprecipitation data. Further examination validated that Smad2/3 enable physical interaction with Keap1, as well as its isoforms and {beta}, by both EDGETSD and DLG motifs in the linker regions between their MH1 and MH2 domains, such that the stability of Smad2/3 and its transcriptional activity are enhanced with the prolonged half-lives and signalling responses from the cytoplasmic to nuclear compartments. The activation of Smad2/3 by Keap1, Keap1 or Keap1{beta} was likely contributable to a coordinative or another competitive effect of Nrf2, particularly in distinct Keap1-based cellular responses to its cognate growth factor or redox stress. Overall, this discovery presents a novel functional bridge crossing both the Keap1-Nrf2 redox signalling and the TGF-{beta}1-Smad2/3 pathways in healthy growth and development.

Redox homeostasis is an integral part of many cellular processes, and its perturbation is associated with conditions such as diabetes, aging, and neurodegenerative disorders. Redox homeostasis or redox potential in organelles is maintained within a particular range to facilitate the organelle specific cellular redox reactions. Previous studies using yeast, cell systems, and nematodes have demonstrated that the Endoplasmic Reticulum (ER) has a more oxidizing environment while the cytosol exhibits a reducing redox potential. However, we know very little about how universal this phenomenon is. We created transgenic zebrafish (Danio rerio) lines with roGFP sensors targeted to the ER and cytosol for studying physiological redox potential at the systems level. In the process, we also characterized the ER-targeting signal sequence in D. rerio for the first time. Measurements of the redox state in live embryos found that the endoplasmic reticulum exhibits deviations from its expected oxidizing redox state in different regions of the developing embryos. The ER is far more reducing than expected in certain tissues of the embryo. Cytosol also exhibited unexpected redox states in some parts of the embryo. Notably, the brain showed regions with unexpected redox states in both the ER and the cytosol. Tissue-specific differences in ER-redox potential became even more evident in a transgenic line expressing the more sensitive roGFPiE variant. Thus, live monitoring of redox potential across the developing zebrafish embryos revealed unanticipated redox states of the ER that will require new biological definitions.

3-hydroxyanthranilate 3,4-dioxygenase (HAAO) is an intermediate enzyme in the conversion from tryptophan (TRP) to nicotinamide adenine dinucleotide (NAD+) via the kynurenine pathway. The kynurenine pathway is the sole de novo NAD+ biosynthetic pathway from ingested tryptophan. Inhibition of several enzymatic steps in the kynurenine pathway increases lifespan in Drosophila melanogaster, Saccharomyces cerevisiae, and Caenorhabditis elegans. Knockout or knockdown of haao-1, the C. elegans gene encoding HAAO, or supplementation of its substrate metabolite 3-hydroxyanthranilic acid (3HAA), has been shown to promote healthy lifespan extension; however, the underlying mechanism remains unknown. In the present study, we report that haao-1 knockdown induces oxidative stress resistance against several reactive oxygen species (ROS) inducing agents by activating the Nrf2/SKN-1 oxidative stress response pathway. An examination of the redox state of animals with reduced haao-1 suggests that activation of the Nrf2/SKN-1 pathway is mediated by shifting the balance toward generation of ROS, generating a hormetic effect. Our results identify a novel mechanism for an endogenous metabolite (3HAA) that activates the oxidative stress response. These results provide a conceptual basis by which modulation of the kynurenine pathway can promote healthy aging and enhanced stress resistance. Graphical Abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=200 SRC="FIGDIR/small/528568v1_ufig1.gif" ALT="Figure 1"> View larger version (73K): org.highwire.dtl.DTLVardef@1563682org.highwire.dtl.DTLVardef@114917dorg.highwire.dtl.DTLVardef@15bc7f2org.highwire.dtl.DTLVardef@a42023_HPS_FORMAT_FIGEXP M_FIG C_FIG HighlightsO_LIKnockdown of haao-1 promotes oxidative stress resistance. C_LIO_LIKnockdown of haao-1 activates the Nrf2/SKN-1 oxidative stress response. C_LIO_LIThe shift in redox balance in haao-1 knockout animals suggests a hormetic mechanism for oxidative stress resistance. C_LI

Oxidative stress is caused by short-lived molecules and metabolic changes belong to the fastest cellular responses. Here we studied how the endothelial cell metabolome reacts to acute oxidative challenges (menadione or H2O2) to identify redox-sensitive metabolic enzymes. H2O2 selectively increased -ketoglutaramate (KGM), a largely uncharacterized metabolite produced by glutamine transamination and a yet unrecognized intermediate of endothelial glutamine catabolism. The enzyme nitrilase-like 2 {omega}-amidase (NIT2) converts KGM to -ketoglutarate (KG). Reversible oxidation of specific cysteine in NIT2 by H2O2 inhibited its catalytic activity. Furthermore, a variant in the NIT2 gene that decreases its expression is associated with high plasma KGM level in humans. Endothelial-specific knockout mice of NIT2 exhibited increased levels of KGM and impaired angiogenesis. Knockout of NIT2 impaired endothelial cell proliferation and sprouting and induced senescence. In conclusion, we show that the glutamine transaminase-{omega}-amidase pathway is a metabolic switch in which NIT2 is the redox-sensitive enzyme. The pathway is modulated in humans and functionally important for endothelial glutamine metabolism.

Iron protoporphyrin IX (heme) is an essential cofactor that is chaperoned in mammalian cells by GAPDH in a process regulated by NO. To gain further understanding we generated a tetra-Cys human GAPDH reporter construct (TC-hGAPDH) which after being expressed and labeled with fluorescent FlAsH reagent could indicate heme binding by fluorescence quenching. When purified or expressed in HEK293T mammalian cells, FlAsH-labeled TC-hGAPDH displayed physical, catalytic, and heme binding properties like native GAPDH and its heme binding (2 mol per tetramer) quenched its fluorescence by 45-65%. In live HEK293T cells we could visualize TC-hGAPDH binding mitochondrially-generated heme and releasing it to the hemeprotein target IDO1 by monitoring cell fluorescence in real time. In cells with active mitochondrial heme synthesis, a low-level NO exposure increased heme allocation into IDO1 while keeping steady the level of heme-bound TC-hGAPDH. When mitochondrial heme synthesis was blocked at the time of NO exposure, low NO caused cells to reallocate existing heme from TC-hGAPDH to IDO1 by a mechanism requiring IDO1 be present and able to bind heme. Higher NO exposure had an opposite effect and caused cells to reallocate existing heme from IDO1 to TC-hGAPDH. Thus, with TC-hGAPDH we could follow mitochondrial heme as it travelled onto and through GAPDH to a downstream target (IDO1) in living cells, and to learn that NO acted at or downstream from the GAPDH heme complex to promote a heme reallocation in either direction depending on the level of NO exposure.

O-GlcNAcylation is a reversible post-translational modification involved the regulation of cytosolic, nuclear and mitochondrial proteins. Only two enzymes, OGT and OGA, control attachment and removal of O-GlcNAc on proteins, respectively. Whereas a variant OGT (mOGT) has been proposed as the main isoform that O-GlcNAcylates proteins in mitochondria, identification of a mitochondrial OGA has not been performed yet. Two splice variants of OGA (short and long isoforms) have been described previously. In this work, using cell fractionation experiments, we show that short-OGA is preferentially recovered in mitochondria-enriched fractions from HEK-293T cells as well as mouse embryonic fibroblasts. Moreover, fluorescent microscopy imaging confirmed that GFP-tagged short-OGA is addressed to mitochondria. In addition, using a BRET-based mitochondrial O-GlcNAcylation biosensor, we show that co-transfection of short-OGA markedly reduced O-GlcNAcylation of the biosensor, whereas long-OGA had no significant effect. Finally, using genetically encoded or chemical fluorescent mitochondrial probes, we showed that short-OGA overexpression increases mitochondrial ROS levels, whereas long-OGA had no significant effect. Together, our work reveals that the short-OGA isoform is targeted to the mitochondria where it regulates ROS homoeostasis.

The oxidant hydrogen peroxide serves as a signaling molecule that alters many aspects of cardiovascular functions. Recent studies suggest that cytoglobin - a hemoglobin expressed in the vasculature - may promote electron transfer reactions with proposed functions in hydrogen peroxide decomposition. Here, we determined the extent to which cytoglobin regulates intracellular hydrogen peroxide and established mechanisms. We found that cytoglobin decreased the hyperoxidation of peroxiredoxins and maintained the activity of peroxiredoxin 2 following challenge with exogenous hydrogen peroxide. Cytoglobin promoted a reduced intracellular environment and facilitated the reduction of the thiol-based hydrogen peroxide sensor Hyper7 after bolus addition of hydrogen peroxide. Cytoglobin also limited the inhibitory effect of hydrogen peroxide on glycolysis and reversed the oxidative inactivation of the glycolytic enzyme GAPDH. Our results indicate that cytoglobin in cells exists primarily as oxyferrous cytoglobin (CygbFe2+-O2) with its cysteine residues in the reduced form. We found that the specific substitution of one of two cysteine residues on cytoglobin (C83A) inhibited the reductive activity of cytoglobin on Hyper7 and GAPDH. Carotid arteries from cytoglobin knockout mice were more sensitive to glycolytic inhibition by hydrogen peroxide than arteries from wildtype mice. Together, these results support a role for cytoglobin in regulating intracellular redox signals associated with hydrogen peroxide through oxidation of its cysteine residues, independent of hydrogen peroxide reaction at its heme center.

Microglia activation causes neuroinflammation, which is a hallmark of neurodegenerative disorders, brain injury, and aging. Ladostigil, a bifunctional reagent with antioxidant and anti-inflammatory properties, reduced microglial activation and enhanced brain functioning in elderly rats. In this study, we studied SH-SY5Y, a human neuroblastoma cell line, and tested viability in the presence of hydrogen peroxide and Sin1 (3-morpholinosydnonimine), which generates reactive oxygen and nitrogen species (ROS/RNS). Both stressors caused significant apoptosis and necrotic cell death that was attenuated by ladostigil. Our results from RNA-seq experiments show that long non-coding RNAs (lncRNAs) account for 30% of all transcripts in SH-SY5Y cells treated with Sin1 for 24 hours. Altogether, we identify 94 differently expressed lncRNAs in the presence of Sin1, including MALAT1, a highly expressed lncRNA with anti-inflammatory and anti-apoptotic functions. Additional activities of Sin-1 upregulated lncRNAs include redox homeostasis (e.g., MIAT, GABPB1-AS1), energy metabolism (HAND2-AS1), and neurodegeneration (e.g., MIAT, GABPB1-AS1, NEAT1). Four lncRNAs implicated as enhancers were significantly upregulated in cells exposed to Sin1 and ladostigil. Finally, we show that H2O2 and Sin1 increased the expression of DJ-1, a redox sensor and modulator of Nrf2 (nuclear factor erythroid 2- related factor 2). Nrf2 (NFE2L2 gene) is a major transcription factor regulating antioxidant genes. In the presence of ladostigil, DJ-1 expression is restored to its baseline. The mechanisms governing SH-SY5Y cell survival and homeostasis are highlighted by the beneficial role of ladostigil in the crosstalk involving Nrf2, antioxidant transcription factor DJ-1, and lncRNAs. Stress-dependent induction of lncRNAs represents an underappreciated regulatory level that contributes to cellular homeostasis and the capacity of SH-SY5Y to cope with oxidative stress.

Different muscles exhibit varied susceptibility to degeneration in Amyotrophic Lateral Sclerosis (ALS), a fatal neuromuscular disorder. Extraocular muscles (EOMs) are particularly resistant to ALS progression, and exploring the underlying molecular nature may offer significant therapeutic value. Reactive aldehyde 4-hydroxynonenal (HNE) is implicated in ALS pathogenesis, and Aldh3a1 is an inactivation-resistant intracellular aldehyde dehydrogenase that detoxifies 4-HNE to protect eyes against UV-induced oxidative stress. We detected prominently higher levels of Aldh3a1 in mouse EOMs compared to other muscles under normal physiological conditions. In an ALS mouse model (hSOD1G93A) reaching end-stage, Aldh3a1 expression was maintained high in EOMs, substantially elevated in soleus and diaphragm, but only moderately increased in extensor digitorum longus (EDL) muscle, which endured the most severe pathological remodeling, as demonstrated by unparalleled upregulation of a denervation marker Ankrd1. Importantly, sciatic nerve transection in wildtype mice further confirmed induced Aldh3a1 and Ankrd1 expression in an inverse manner across muscle types in response to denervation. Mechanistically, whole-muscle RNA-Seq and pharmacological tests indicate that higher basal levels of lipid oxidation in soleus and diaphragm muscles may predispose them to stronger Nrf2 antioxidant responses under pathological stress compared to EDL, leading to more prominent Aldh3a1 upregulation. Additionally, the identification of the myoblast fusion marker Mymk as an EOM signature gene suggests that the spontaneous activation of satellite cells contributes to high levels of Aldh3a1 in EOMs. Functionally, adeno-associated virus-mediated overexpression of Aldh3a1 protected myotubes from 4-HNE-induced DNA fragmentation and plasma membrane leakage. It also restored MG53-mediated membrane repair, highlighting its potential for clinical applications.

Hydrogen peroxide (H2O2) and lipid hydroperoxides (LOOH) are initiators and transducers of inter- and intra-cellular signaling in response to diverse environmental, pathological and developmental cues. The accumulation of both H2O2 and LOOH is often temporally and spatially coincident in tissues, but it is unknown if this coincidence extends to subcellular compartments. If distinct accumulation of different peroxides occurs at this smaller spatial scale, then it would be an important factor in signaling specificity. Fusion of the redox-sensitive (ro)GFP2 to the Saccharomyces cerevisiae (yeast) OXIDANT RECEPTOR PEROXIDASE1 (ORP1), also known as GLUTATHIONE PEROXIDASE3 (GPX3), created a now widely used biosensor that is assumed to detect H2O2 in vivo. This is despite monomeric GPX enzymes, such as ORP1/GPX3, possessing wide peroxide substrate specificities. Consequently, we confirmed in vitro that roGFP2-ORP1 is not only oxidized by H2O2, but also by phospholipid fatty acid peroxides generated in lecithin-derived liposomes by lipoxygenase-catalyzed peroxidation. This led us to doubt that roGFP2-ORP1 in vivo is specific for H2O2. To address this issue of peroxide specificity, we constructed a modified biosensor called roGFP2-synORP1. This version has greatly diminished reactivity towards phospholipid fatty acid peroxides but retains high sensitivity for H2O2. These two roGFP2-based biosensors, targeted to chloroplasts, cytosol and the nucleus, were quantitatively imaged in parallel in Nicotiana benthamiana abaxial epidermal cells experiencing high light- and herbicide-induced photo-oxidative stress. From differential patterns of oxidation of these probes, we inferred that the chloroplasts accumulated both peroxide types. In contrast, LOOH and H2O2 accumulated exclusively in the cytosol and nucleus respectively. Therefore, this suggests that the signalling networks initiated by different peroxides will have a distinct spatial component.