Reactive Oxygen Species Tolerance Research Articles

Role of Antioxidant Molecules in the Oxidative Stress Response Networks in the Tangerine Pathotype of Alternaria alternata

Antioxidant molecules play a crucial role in maintaining redox homeostasis, eliminating oxidative damage, and regulating pathogenesis in phytopathogenic fungi. These antioxidants function through a complex regulatory network involving enzymatic scavengers such as the superoxide dismutases (SODs), catalases, thioredoxins, and glutathiones, as well as non-enzymatic molecules. Specifically, the thioredoxin and glutathione systems (AaTrr1, AaTsa1, AaGpx3, and AaGlr1) mediated by NADPH oxidase represent vital thiol antioxidant systems utilized to regulate the detoxification of reactive oxygen species (ROS) in Alternaria alternata. This present study investigated the regulatory roles of AaBemA, a component of the fungal NADPH oxidase (Nox) complex, in the tangerine pathotype of A. alternata. Loss-of-function genetic analysis demonstrated that AaBemA is essential for the accumulation of cellular hydrogen peroxide (H2O2). Mutant strains with defective AaBemA displayed higher sensitivity to H2O2 and the ROS-generating oxidant tert-butyl-hydroperoxide. These phenotypes closely resembled those previously observed in AaNoxB, AaTrr1, AaTsa1, AaGlr1, and AaYap1 mutants, suggesting a potential interconnection among them. Notably, the defective phenotype of ΔAaBemA could be restored through genetic complementation with wildtype AaBemA gene. Subcellular localization of a functional AaBemA fused with green fluorescent protein (GFP) gene under confocal microscope revealed a widespread distribution of green fluorescence in the cytoplasm and cell membrane, indicating high expression of AaBemA during fungal growth in A. alternata. Intriguingly, inactivation of AaBemA did not affect the morphological phenotype and pathogenicity, indicating that the AaBemA is dispensable for the aforementioned phenotypes. To explore the molecular mechanisms underlying the regulation of ROS stress response, we sequenced the whole transcriptomes of A. alternata wildtype and ROS-sensitive mutants (ΔAaBemA, ΔAaNoxB, ΔAaGlr1, ΔAaTrr1, ΔAaTsa1, ΔAaYap1) which displayed considerable sensitivity to oxidants. Comparative transcriptome analysis revealed significant influence on the gene-expression pattern of numerous genes related to glutathione metabolism, cellular oxidant detoxification, cellular response to abiotic stimulus, and cellular response to osmotic stress. The gene-expression data and pathways related to various essential metabolic processes and ROS tolerance enabled us to propose a NADPH oxidase-mediated regulatory network involving NADPH oxidase (AaNoxB, AaBemA), AaYap1, glutaredoxin (AaGPx3, AaGlr1), and thioredoxin systems (AaTrr1, AaTsa1) in responding to ROS stress in A. alternata.

White Collar 1 Modulates Oxidative Sensitivity and Virulence by Regulating the HOG1 Pathway in Fusarium asiaticum.

Fusarium asiaticum is an epidemiologically important pathogen of cereal crops in east Asia, accounting for both yield losses and mycotoxin contamination problems in food and feed products. FaWC1, a component of the blue-light receptor White Collar complex (WCC), relies on its transcriptional regulatory zinc finger domain rather than the light-oxygen-voltage domain to regulate pathogenicity of F. asiaticum, although the downstream mechanisms remain obscure. In this study, the pathogenicity factors regulated by FaWC1 were analyzed. It was found that loss of FaWC1 resulted in higher sensitivity to reactive oxygen species (ROS) than in the wild type, while exogenous application of the ROS quencher ascorbic acid restored the pathogenicity of the ΔFawc1 strain to the level of the wild type, indicating that the reduced pathogenicity of the ΔFawc1 strain is due to a defect in ROS tolerance. Moreover, the expression levels of the high-osmolarity glycerol (HOG) mitogen-activated protein kinase (MAPK) pathway genes and their downstream genes encoding ROS scavenging enzymes were downregulated in the ΔFawc1 mutant. Upon ROS stimulation, the FaHOG1-green fluorescent protein (GFP)-expressing signal driven by the native promoter was inducible in the wild type but negligible in the ΔFawc1 strain. Overexpressing Fahog1 in the ΔFawc1 strain could recover the ROS tolerance and pathogenicity of the ΔFawc1 mutant, but it remained defective in light responsiveness. In summary, this study dissected the roles of the blue-light receptor component FaWC1 in regulating expression levels of the intracellular HOG-MAPK signaling pathway to affect ROS sensitivity and pathogenicity in F. asiaticum. IMPORTANCE The well-conserved fungal blue-light receptor White Collar complex (WCC) is known to regulate virulence of several pathogenic species for either plant or human hosts, but how WCC determines fungal pathogenicity remains largely unknown. The WCC component FaWC1 in the cereal pathogen Fusarium asiaticum was previously found to be required for full virulence. The present study dissected the roles of FaWC1 in regulating the intracellular HOG MAPK signaling pathway to affect ROS sensitivity and pathogenicity in F. asiaticum. This work thus extends knowledge of the association between fungal light receptors and the intracellular stress signaling pathway to regulate oxidative stress tolerance and pathogenicity in an epidemiologically important fungal pathogen of cereal crops.

Fibronectin-Enriched Interface Using a Spheroid-Converged Cell Sheet for Effective Wound Healing.

Cell sheets and spheroids are cell aggregates with excellent tissue-healing effects. However, their therapeutic outcomes are limited by low cell-loading efficacy and low extracellular matrix (ECM). Preconditioning cells with light illumination has been widely accepted to enhance reactive oxygen species (ROS)-mediated ECM expression and angiogenic factor secretion. However, there are difficulties in controlling the amount of ROS required to induce therapeutic cell signaling. Here, we develop a microstructure (MS) patch that can culture a unique human mesenchymal stem cell complex (hMSCcx), spheroid-attached cell sheets. The spheroid-converged cell sheet structure of hMSCcx shows high ROS tolerance compared to hMSC cell sheets owing to its high antioxidant capacity. The therapeutic angiogenic efficacy of hMSCcx is reinforced by regulating ROS levels without cytotoxicity using light (610 nm wavelength) illumination. The reinforced angiogenic efficacy of illuminated hMSCcx is based on the increased gap junctional interaction by enhanced fibronectin. hMSCcx engraftment is significantly improved in our novel MS patch by means of ROS tolerative structure of hMSCcx, leading to robust wound-healing outcomes in a mouse wound model. This study provides a new method to overcome the limitations of conventional cell sheets and spheroid therapy.

The effect of temperature conditioning (9°C and 20°C) on the proteome of entomopathogenic nematode infective juveniles.

Entomopathogenic nematodes (EPN) of the genera Steinernema and Heterorhabditis are parasites which kill and reproduce within insects. While both have life cycles centred around their developmentally arrested, nonfeeding and stress tolerant infective juvenile (IJ) stage, they are relatively distantly related. These IJs are promising biocontrol agents, and their shelf life and stress tolerance may be enhanced by storage at low temperatures. The purpose of this study was to investigate how the proteome of the IJs of two distantly related EPN species is affected by storage at 9°C (for up to 9 weeks) and 20°C (for up to 6 weeks), using label-free quantitative proteomics. Overall, more proteins were detected in S. carpocapsae (2422) than in H. megidis (1582). The S. carpocapsae proteome was strongly affected by temperature, while the H. megidis proteome was affected by both time and temperature. The proteins which increased in abundance to the greatest extent in S. carpocapsae IJs after conditioning at 9°C were chaperone proteins, and proteins related to stress. The proteins which increased in abundance the most after storage at 20°C were proteins related to the cytoskeleton, cell signalling, proteases and their inhibitors, which may have roles in infection. The proteins which decreased in abundance to the greatest extent in S. carpocapsae after both 9°C and 20°C storage were those associated with metabolism, stress and the cytoskeleton. After storage at both temperatures, the proteins increased to the greatest extent in H. megidis IJs were those associated with the cytoskeleton, cell signalling and carbon metabolism, and the proteins decreased in abundance to the greatest extent were heat shock and ribosomal proteins, and those associated with metabolism. As the longest-lived stage of the EPN life cycle, IJs may be affected by proteostatic stress, caused by the accumulation of misfolded proteins and toxic aggregates. The substantial increase of chaperone proteins in S. carpocapsae, and to a greater extent at 9°C, and the general decrease in ribosomal and chaperone proteins in H. megidis may represent species-specific proteostasis mechanisms. Similarly, organisms accumulate reactive oxygen species (ROS) over time and both species exhibited a gradual increase in proteins which enhance ROS tolerance, such as catalase. The species-specific responses of the proteome in response to storage temperature, and over time, may reflect the phylogenetic distance and/or different ecological strategies.

Analysis of the Streptococcus mutans Proteome during Acid and Oxidative Stress Reveals Modules of Protein Coexpression and an Expanded Role for the TreR Transcriptional Regulator.

ABSTRACTStreptococcus mutans promotes a tooth-damaging dysbiosis in the oral microbiota because it can form biofilms and survive acid stress better than most of its ecological competitors, which are typically health associated. Many of these commensals produce hydrogen peroxide; therefore, S. mutans must manage both oxidative stress and acid stress with coordinated and complex physiological responses. In this study, the proteome of S. mutans was examined during regulated growth in acid and oxidative stresses as well as in deletion mutants with impaired oxidative stress phenotypes, Δnox and ΔtreR. A total of 607 proteins exhibited significantly different abundances across the conditions tested, and correlation network analysis identified modules of coexpressed proteins that were responsive to the deletion of nox and/or treR as well as acid and oxidative stress. The data explained the reactive oxygen species (ROS)-sensitive and mutacin-deficient phenotypes exhibited by the ΔtreR strain. SMU.1069-1070, a poorly understood LytTR system, had an elevated abundance in the ΔtreR strain. S. mutans LytTR systems regulate mutacin production and competence, which may explain how TreR affects mutacin production. Furthermore, the protein cluster that produces mutanobactin, a lipopeptide important in ROS tolerance, displayed a reduced abundance in the ΔtreR strain. The role of Nox as a keystone in the oxidative stress response was also emphasized. Crucially, this data set provides oral health researchers with a proteome atlas that will enable a more complete understanding of the S. mutans stress responses that are required for pathogenesis, and will facilitate the development of new and improved therapeutic approaches for dental caries.IMPORTANCE Dental caries is the most common chronic infectious disease worldwide and disproportionately affects marginalized socioeconomic groups. Streptococcus mutans is considered a primary etiological agent of caries, with its pathogenicity being dependent on coordinated physiological stress responses that mitigate the damage caused by the oxidative and acid stress common within dental plaque. In this study, the proteome of S. mutans was examined during growth in acidic and oxidative stresses as well in nox and treR deletion mutants. A total of 607 proteins were differentially expressed across the strains/growth conditions, and modules of coexpressed proteins were identified, which enabled mapping the acid and oxidative stress responses across S. mutans metabolism. The presence of TreR was linked to mutacin production via LytTR system signaling and to oxidative stress via mutanobactin production. The data provided by this study will guide future research elucidating S. mutans pathogenesis and developing improved preventative and treatment modalities for dental caries.

Genomic Analysis of Soybean PP2A-B Family and Its Effects on Drought and Salt Tolerance.

Abiotic stresses induce the accumulation of reactive oxygen species (ROS) and significantly affect plant growth. Protein phosphatase 2A (PP2A) plays an important role in controlling intracellular and extracellular ROS signals. However, the interaction between PP2A, ROS, and stress tolerance remains largely unclear. In this study, we found that the B subunit of PP2A (PP2A-B) can be significantly induced and was analyzed using drought- and salt-induced soybean transcriptome data. Eighty-three soybean PP2A-B genes were identified from the soybean genome via homologous sequence alignment, which was distributed across 20 soybean chromosomes. Among soybean PP2A-B family genes, 26 GmPP2A-B members were found to be responsive to drought and salt stresses in soybean transcriptome data. Quantitative PCR (qPCR) analysis demonstrated that GmPP2A-B71 had the highest expression levels under salt and drought stresses. Functional analysis demonstrated that overexpression of GmPP2A-B71 in soybeans can improve plant tolerance to drought and salt stresses; however, the interference of GmPP2A-B71 in soybean increased the sensibility to drought and salt stresses. Further analysis demonstrated that overexpression of GmPP2A-B71 in soybean could enhance the expression levels of stress-responsive genes, particularly genes associated with ROS elimination. These results indicate that PP2A-B can promote plant stress tolerance by regulating the ROS signaling, which will contribute to improving the drought resistance of crops.

Differential modulation of photosynthesis, ROS and antioxidant enzyme activities in stress-sensitive and -tolerant rice cultivars during salinity and drought upon restriction of COX and AOX pathways of mitochondrial oxidative electron transport

Drought and salt stresses are two major abiotic stress factors that hamper crop growth and productivity. Three rice cultivars with different sensitivity and tolerance towards abiotic stress were used in the current study. While cultivar Aiswarya is salt- and drought-sensitive, cultivar Vyttila is salt-tolerant and cultivar Vaisakh is drought-tolerant. We compared the physiological and biochemical responses of these rice cultivars under salt and drought stress conditions after restricting their cytochrome oxidase (COX) and alternative oxidase (AOX) pathways using antimycin A and salicylhydroxamic acid treatment. Further, changes in their expression of AOX genes and corresponding protein levels were compared and analysed. The sensitive and tolerant rice cultivars subjected to drought and salt stress showed differential responses in physiological and biochemical traits. Whereas Aiswarya showed clear phenotypic differences, such as stunted growth, leaf curling, and loss of greening in leaf tissues, with increase in salt content and progressive drought stress, Vyttila and Vaisakh showed no remarkable changes. Moreover, the drought-tolerant cultivar rehydrated after 10 days of drought exposure, whereas the sensitive variety did not show any rehydration of leaf tissue. The leaves of the tolerant cultivars showed lower reactive oxygen species (ROS) production than that of the sensitive plants under drought and salt stress conditions because of the activation of a stronger antioxidant defence. Although, the restriction of COX and AOX pathways increased the susceptibility of sensitive cultivars, it affected the tolerant varieties moderately. Higher photosynthetic rates, an efficient antioxidant system comprising higher superoxide dismutase, ascorbate peroxidase, and catalase activity along with higher AOX1a gene expression levels during drought and salt stress were observed in tolerant cultivars. The results suggest that an efficient antioxidant system and increased transcription of the AOX1a gene along with higher AOX protein levels are important for tolerant rice cultivars to maintain higher photosynthesis rates, lower ROS, and stress tolerance. Restriction of COX and AOX pathways impact the photosynthesis, ROS, and antioxidant enzymes in both sensitive and tolerant cultivars. The restriction of COX and AOX pathways have a stronger impact on gas exchange and fluorescence parameters of the sensitive cultivar than on that of the tolerant cultivars owing to the higher photosynthetic rates in tolerant cultivars.

Bacillus velezensis tolerance to the induced oxidative stress in root colonization contributed by the two-component regulatory system sensor ResE.

Efficient root colonization of plant growth-promoting rhizobacteria is critical for their plant-beneficial functions. However, the strategy to overcome plant immunity during root colonization is not well understood. In particular, how Bacillus strains cope with plant-derived reactive oxygen species (ROS), which function as the first barrier of plant defence, is not clear. In the present study, we found that the homolog of flg22 in Bacillus velezensis SQR9 (flg22SQR9 ) has 78.95% identity to the typical flg22 (flg22P.s. ) and induces a significant oxidative burst in cucumber and Arabidopsis. In contrast to pathogenic or beneficial Pseudomonas, live B. velezensis SQR9 also induced an oxidative burst in cucumber. We further found that B. velezensis SQR9 tolerated higher H2 O2 levels than Pst DC3000, the pathogen that harbours the typical flg22, and that it possesses the ability to suppress the flg22-induced oxidative burst, indicating that B. velezensis SQR9 may exploit a more efficient ROS tolerance system than DC3000. Further experimentation with mutagenesis of bacteria and Arabidopsis showed that the two-component regulatory system, ResDE, in B. velezensis SQR9 is involved in tolerance to plant-derived oxidative stress, thus contributing to root colonization. This study supports a further investigation of the interaction between beneficial rhizobacteria and plant immunity.

Cascaded Amplifier Nanoreactor for Efficient Photodynamic Therapy.

Photodynamic therapy (PDT) utilizes reactive oxygen species (ROS) to treat established diseases and has attracted growing attention in the field of cancer therapy. However, in a tumor microenvironment (TME), the inherent hypoxia and high level of antioxidants severely hamper the efficacy of ROS generation. Here, we describe a cascaded amplifier nanoreactor based on self-assembled nanofusiforms for persistent oxygenation to amplify ROS levels. The nanofusiform assembly is capable of photothermal and photodynamic treatment and regulation of redox oxidation stress by antioxidant depletion to prevent ROS tolerance. The Pt nanozyme decoration of the nanofusiform enables efficient oxygen supplements via Pt nanozyme-catalyzed decomposition of H2O2 overexpressed in TME and generation of O2. Furthermore, the temperature elevation resulted from the photothermal effect of the nanofusiform increases the catalase-like catalytic activity of the Pt nanozyme for boosted oxygen generation. Thus, such a triple cascade strategy using nanozyme-based nanofusiforms amplifies the ROS level by continuous oxygenation, enhancing the efficacy of PDT in vitro and in vivo. Meanwhile, an in vivo multi-modal imaging including near-infrared fluorescence imaging, photothermal imaging, and magnetic resonance imaging achieves precise tumor diagnosis. The rationally designed nanofusiform acts as an efficient ROS amplifier through multidimension strengthening of continuous oxygenation, providing a potential smart nanodrug for cancer therapy.

The critical role of MetR/MetB/MetC/MetX in cysteine and methionine metabolism, fungal development and virulence of Alternaria alternata.

Methionine is a unique sulfur-containing amino acid, which plays an important role in biological protein synthesis and various cellular processes. Here, we characterized the biological functions of AaMetB, AaMetC, and AaMetX in the tangerine pathotype of Alternaria alternata Morphological analysis showed that the mutants lacking AaMetB, AaMetC, or AaMetX resulted in less aerial hypha and fewer conidia in artificial media. Pathogenicity analysis showed that AaMetB, AaMetC, and AaMetX are required for full virulence. The defects in vegetative growth, conidiation and virulence of ΔMetB, ΔMetC, and ΔMetX can be restored by exogenous methionine and homocysteine, indicating that AaMetB, AaMetC, and AaMetX are required for methionine biosynthesis. However, exogenous cysteine only restored the growth and virulence defects of ΔMetR but not ΔMetB/C/X, suggesting that AaMetR is essential for cysteine biosynthesis. Oxidant sensitivity assay showed that only ΔMetR is sensitive to H2O2 and many ROS-generating compounds, indicating that AaMetR is essential for oxidative tolerance. Interestingly, fungicides indoor bioassays showed that only the ΔMetR mutants are susceptive to chlorothalonil, a fungicide that could bind to the cysteine of glyceraldehyde-3-phosphate dehydrogenase. Comparative transcriptome analysis showed that the inactivation of MetB, MetC, MetX, or MetR significantly affected the expression of methionine metabolism-related genes. Moreover, the inactivation of AaMetR significantly affected the expression of many genes related to glutathione metabolism, which is essential for ROS tolerance. Taken together, our study provides genetic evidence to define the critical roles of AaMetB, AaMetC, AaMetX, and AaMetR in cysteine and methionine metabolism, fungal development and virulence of Alternaria alternata IMPORTANCE The transcription factor METR regulating methionine metabolism is essential for reactive oxygen species (ROS) tolerance and virulence in many phytopathogenic fungi. However, the underlying regulatory mechanism of METR involved in this process is still unclear. In the present study, we generated AaMetB, AaMetC and AaMetX deletion mutants and compared these mutants with AaMetR disrupted mutants. Interestingly, we found that AaMetB, AaMetC and AaMetX are required for vegetative growth, conidiation, and pathogenicity in Alternaria alternata, but not for ROS tolerance and cysteine metabolism. Furthermore, we found that METR is involved in the biosynthesis of cysteine, which is an essential substrate for the biosynthesis of methionine and glutathione. This study emphasizes the critical roles of MetR, MetB, MetC, MetX in the regulation of cysteine and methionine metabolism, as well as the cross-link with glutathione-mediated ROS tolerance in phytopathogenic fungi, which provides a foundation for future investigations.

Maize SRO1e represses anthocyanin synthesis through regulating the MBW complex in response to abiotic stress.

Plants experiencing abiotic stress react by generating reactive oxygen species (ROS), compounds that, if allowed to accumulate to excess, repress plant growth and development. Anthocyanins induced by abiotic stress are strong antioxidants that neutralize ROS, whereas their over-accumulation retards plant growth. Although the mechanism of anthocyanin synthesis has been revealed, how plants balance anthocyanin synthesis under abiotic stress to maintain ROS homeostasis is unknown. Here, ROS-related proteins, SIMILAR TO RCD-ONEs (SROs), were analysed in Zea mays (maize), and all six SRO1 genes were inducible by a variety of abiotic stress agents. The constitutive expression of one of these genes, ZmSRO1e, in maize as well as in Arabidopsis thaliana increased the sensitivity of the plant to abiotic stress, but repressed anthocyanin biosynthesis and ROS scavenging activity. Loss-of-function mutation of ZmSRO1e enhanced ROS tolerance and anthocyanin accumulation. We showed that ZmSRO1e competed with ZmR1 (a core basic helix-loop-helix subunit of the MYB-bHLH-WD40 transcriptional activation complex) for binding with ZmPL1 (a core MYB subunit of the complex). Thus, during the constitutive expression of ZmSRO1e, the formation of the complex was compromised, leading to the repression of genes, such as ZmA4 (encoding dihydroflavonol reductase), associated with anthocyanin synthesis. Overall, the results have revealed a mechanism that allows the products of maize SRO1e to participate in the abiotic stress response.

Dexmedetomidine alleviated neuropathic pain in dorsal root ganglion neurons by inhibition of anaerobic glycolysis activity and enhancement of ROS tolerance.

Neuropathic pain is a kind of chronic pain that is triggered or caused primarily by damage to the nervous system and neurological dysfunction. It’s known that dexmedetomidine is a new type of highly selective alpha2-adrenoceptor agonist with sedation, anti-anxiety, analgesic and other effects. However, the function and mechanism of dexmedetomidine on neuropathic pain are not clear. Rat DRG neurons were isolated and identified using immunofluorescence assay. Following treatment with H2O2, dexmedetomidine or ROS inhibitor (NAC), the apoptosis and ROS levels were examined by flow cytometery; apoptosis- and anaerobic glycolysis-related proteins were determined by Western blot assay; glucose consumption, pyruvic acid, lactic acid and ATP/ADP ratios were also measured. The results revealed that dexmedetomidine inhibited H2O2-induced apoptosis and reactive oxygen species (ROS) in rat DRG neurons and in addition, dexmedetomidine down-regulated the expression levels of anaerobic glycolysis-related proteins, significantly reduced glucose, pyruvic acid and lactic acid levels. It also increased the ATP/ADP ratio in H2O2-treated rat dorsal root ganglion (DRG) neurons. Moreover, we also demonstrated that ROS inhibitor (NAC) also inhibited H2O2-induced apoptosis and anaerobic glycolysis in rat DRG neurons. In conclusion, dexmedetomidine suppressed H2O2-induced apoptosis and anaerobic glycolysis activity by inhibiting ROS, in rat DRG neurons. Therefore, dexmedetomidine might play a pivotal role in neuropathic pain by the inhibition of ROS.

Heme Oxygenase-1 Is a Pivotal Modulator of Bone Turnover and Remodeling: Molecular Implications for Prostate Cancer Bone Metastasis.

Aims: Bone is the most frequent site of prostate cancer (PCa) metastasis. Tumor cells interact with the bone microenvironment interrupting tissue balance. Heme oxygenase-1 (HO-1; encoded by Hmox1) appears as a potential target in PCa maintaining the cellular homeostasis. Our hypothesis is that HO-1 is implicated in bone physiology and modulates the communication with PCa cells. Here we aimed at (i) assessing the physiological impact of Hmox1 gene knockout (KO) on bone metabolism in vivo and (ii) determining the alterations of the transcriptional landscape associated with tumorigenesis and bone remodeling in cells growing in coculture (PCa cells with primary mouse osteoblasts [PMOs] from BALB/c Hmox1+/+, Hmox1+/-, and Hmox1-/- mice). Results: Histomorphometric analysis of Hmox1-/- mice bones exhibited significantly decreased bone density with reduced remodeling parameters. A positive correlation between Hmox1 expression and Runx2, Col1a1, Csf1, and Opg genes was observed in PMOs. Flow cytometry studies revealed two populations of PMOs with different reactive oxygen species (ROS) levels. The high ROS population was increased in PMOs Hmox1+/- compared with Hmox1+/+, but was significantly reduced in PMOs Hmox1-/-, suggesting restrained ROS tolerance in KO cells. Gene expression was altered in PMOs upon coculture with PCa cells, showing a pro-osteoclastic profile. Moreover, HO-1 induction in PCa cells growing in coculture with PMOs resulted in a significant modulation of key bone markers such as PTHrP and OPG. Innovation and Conclusion: We here demonstrate the direct implications of HO-1 expression in bone remodeling and how it participates in the alterations in the communication between bone and prostate tumor cells.

NADH peroxidase plays a crucial role in consuming H2O2 in Lactobacillus casei IGM394.

The facultative anaerobic bacterium Lactobacillus casei IGM394 is used as a host for drug delivery systems, and it exhibits the same growth rate under aerobic and anaerobic conditions. L. casei strains carry several genes that facilitate oxygen and reactive oxygen species (ROS) tolerance in their genomes, but their complete functions have not been uncovered. To clarify the oxygen and ROS tolerance mechanisms of L. casei IGM394, we constructed 23 deficient mutants targeting genes that confer oxidative stress resistance. Significantly decreased growth and high H2O2 accumulation were observed in the NADH peroxidase gene-mutated strain (Δnpr) compared with the findings in the wild type. The H2O2 degradation capacity of Δnpr revealed that NADH peroxidase is a major H2O2-degrading enzyme in L. casei IGM394. Interestingly, ΔohrR, a mutant deficient in the organic hydroperoxide (OhrA) repressor, exhibited higher H2O2 resistance than the wild-type strain. Increased Npr expression and H2O2 degradation ability were observed in ΔohrR, further supporting the importance of OhrA to ROS tolerance mechanisms. The other mutants did not exhibit altered growth rates, although some mutants had higher growth in the presence of oxygen. From these results, it is presumed that L. casei IGM394 has multiple oxygen tolerance mechanisms and that the loss of a single gene does not alter the growth rate because of the presence of complementary mechanisms. Contrarily, the H2O2 tolerance mechanism is solely dependent on NADH peroxidase in L. casei IGM394.

Identification of QTL Related to ROS Formation under Hypoxia and Their Association with Waterlogging and Salt Tolerance in Barley.

Waterlogging is a serious environmental problem that limits agricultural production in low-lying rainfed areas around the world. The major constraint that plants face in a waterlogging situation is the reduced oxygen availability. Accordingly, all previous efforts of plant breeders focused on traits providing adequate supply of oxygen to roots under waterlogging conditions, such as enhanced aerenchyma formation or reduced radial oxygen loss. However, reduced oxygen concentration in waterlogged soils also leads to oxygen deficiency in plant tissues, resulting in an excessive accumulation of reactive oxygen species (ROS) in plants. To the best of our knowledge, this trait has never been targeted in breeding programs and thus represents an untapped resource for improving plant performance in waterlogged soils. To identify the quantitative trait loci (QTL) for ROS tolerance in barley, 187 double haploid (DH) lines from a cross between TX9425 and Naso Nijo were screened for superoxide anion (O2•−) and hydrogen peroxide (H2O2)—two major ROS species accumulated under hypoxia stress. We show that quantifying ROS content after 48 h hypoxia could be a fast and reliable approach for the selection of waterlogging tolerant barley genotypes. The same QTL on chromosome 2H was identified for both O2•− (QSO.TxNn.2H) and H2O2 (QHP.TxNn.2H) contents. This QTL was located at the same position as the QTL for the overall waterlogging and salt tolerance reported in previous studies, explaining 23% and 24% of the phenotypic variation for O2•− and H2O2 contents, respectively. The analysis showed a causal association between ROS production and both waterlogging and salt stress tolerance. Waterlogging and salinity are two major abiotic factors affecting crop production around the globe and frequently occur together. The markers associated with this QTL could potentially be used in future breeding programs to improve waterlogging and salinity tolerance.

FITNESS, a CCT domain-containing protein, deregulates reactive oxygen species levels and leads to fine-tuning trade-offs between reproductive success and defence responses in Arabidopsis.

Environmental stresses are the major factors that limit productivity in plants. Here, we report on the function of an uncharacterized gene At1g07050, encoding a CCT domain-containing protein, from Arabidopsis thaliana. At1g07050 expression is highly repressed by oxidative stress. We used metabolomics, biochemical, and genomic approaches to analyse performance of transgenic lines with altered expression of At1g07050 under normal and oxidative stress conditions. At1g07050 overexpressing lines showed increased levels of reactive oxygen species (ROS), whereas knock-out mutants exhibited decreased levels of ROS and higher tolerance to oxidative stress generated in the chloroplast. Our results uncover a role for At1g07050 in cellular redox homeostasis controlling H2 O2 levels, due to changes in enzymes, metabolites, and transcripts related to ROS detoxification. Therefore, we call this gene FITNESS. Additionally, several genes such as ACD6, PCC1, and ICS1 related to salicylic acid signalling and defence were found differentially expressed among the lines. Notably, FITNESS absence significantly improved seed yield suggesting an effective fine-tuning trade-off between reproductive success and defence responses.

Depressive-Like Behaviors Are Regulated by NOX1/NADPH Oxidase by Redox Modification of NMDA Receptor 1.

Involvement of reactive oxygen species (ROS) has been suggested in the development of psychiatric disorders. NOX1 is a nonphagocytic form of NADPH oxidase whose expression in the nervous system is negligible compared with other NOX isoforms. However, NOX1-derived ROS increase inflammatory pain and tolerance to opioid analgesia. To clarify the role of NOX1 in the brain, we examined depressive-like behaviors in mice deficient in Nox1 (Nox1-/Y). Depressive-like behaviors induced by chronic social defeat stress or administration of corticosterone (CORT) were significantly ameliorated in Nox1-/Y Generation of ROS was significantly elevated in the prefrontal cortex (PFC) of mice administrated with CORT, while NOX1 mRNA was upregulated only in the ventral tegmental area (VTA) among brain areas responsible for emotional behaviors. Delivery of miRNA against NOX1 to VTA restored CORT-induced depressive-like behaviors in wild-type (WT) littermates. Administration of CORT to WT, but not to Nox1-/Y, significantly reduced transcript levels of brain-derived neurotrophic factor (bdnf), with a concomitant increase in DNA methylation of the promoter regions in bdnf Delivery of miRNA against NOX1 to VTA restored the level of BDNF mRNA in WT PFC. Redox proteome analyses demonstrated that NMDA receptor 1 (NR1) was among the molecules redox regulated by NOX1. In cultured cortical neurons, hydrogen peroxide significantly suppressed NMDA-induced upregulation of BDNF transcripts in NR1-expressing cells but not in cells harboring mutant NR1 (C744A). Together, these findings suggest a key role of NOX1 in depressive-like behaviors through NR1-mediated epigenetic modification of bdnf in the mesoprefrontal projection.SIGNIFICANCE STATEMENT NADPH oxidase is a source of reactive oxygen species (ROS) that have been implicated in the pathogenesis of various neurological disorders. We presently showed the involvement of a nonphagocytic type of NADPH oxidase, NOX1, in major depressive disorders, including behavioral, biochemical, and anatomical changes in mice. The oxidation of NR1 by NOX1-derived ROS was demonstrated in prefrontal cortex (PFC), which may be causally linked to the downregulation of BDNF, promoting depressive-like behaviors. Given that NOX1 is upregulated only in VTA but not in PFC, mesocortical projections appear to play a crucial role in NOX1-dependent depressive-like behaviors. Our study is the first to present the potential molecular mechanism underlying the development of major depression through the NOX1-induced oxidation of NR1 and epigenetic modification of bdnf.

Estrogen potentiates reactive oxygen species (ROS) tolerance to initiate carcinogenesis and promote cancer malignant transformation.

Estrogen-mediated high reactive oxygen species (ROS) tolerance plays an important role in driving carcinogenesis. ROS overproduction acts as the significant effector to increase genomic instability and transduce redox-related signal pathway. Especially, estrogen-mediated mitochondrial ROS promote the mutations in mitochondrial DNA (mtDNA) and the damage to mitochondrial proteins. Moreover, estrogen-mediated ROS contribute to the alteration of energy metabolism and modulate several redox-sensitive proteins responsible for cell proliferation and anti-apoptosis. On the other hand, estrogen simultaneously performs the antioxidative beneficial functions, which protects cancer cells from the potential cytotoxic effects of estrogen-mediated ROS through activation of nuclear factor-erythroid-2-related factor 2 (Nrf2)/Kelch-like ECH-associated protein 1 (Keap1) antioxidant response. Consequently, estrogen potentiates the high ROS tolerance through increase of ROS production as well as acceleration of ROS elimination, which ultimately results in estrogen-mediated carcinogenesis and malignant transformation. However, this overdependence on antioxidant response system to resist ROS-mediated cytotoxicity also represents the "Achilles' Heel" of estrogen-mediated cancer cells. In other words, the destruction of the high ROS tolerance using antioxidant inhibitors may provide a novel and efficacious measure to selectively eliminate these cancer cells without harming normal cells. Of course, it will be necessary to define the exact situation of ROS homeostasis in the different cellular microenvironment and further decipher the mechanisms of redox regulation, which is consequently used as a new avenue to optimize the clinical therapy for estrogen-mediated cancer.

Abstract 2431: Co-targeting ROS and CLU-mediated stress response using SMIP004 (a novel inducer of ROS and cancer cell selective apoptosis) and OGX-011 in MDV3100-resistant, castrate-resistant prostate cancer

Abstract Prostate cancer is the most common male carcinoma in North America and the second leading cause of cancer related death in men. While new drugs targeting Androgen Receptor (AR), like abiraterone and MDV3100, significantly increase survival of patients with castration resistant prostate cancer (CRPC), many patients still die of metastatic resistant disease. Continued therapeutic improvements towards prolonging the chronicity of CRPC will require characterization of innate and stress-activated survival responses, and rational combinatorial co-targeting strategies designed to abrogate them. OGX-011 is a second generation antisense oligonucleotide targeting Clusterin (CLU) currently under evaluation in phase III clinical trials. CLU is a molecular chaperone involved in endoplasmic reticulum (ER) stress, protein homeostasis and in many signaling and transcriptional survival networks. It is cytoprotective under stress conditions and correlated with treatment resistance in prostate and other cancers. SMIP004 is a novel drug that modulates cell cycle and ER stress and unfolded protein responses (UPR). Some of its fuctions have been correlated to Reactive Oxygen Species (ROS) modulation. However, the exact mechanisms of action of SMIP004 are not completely understood. Cell survival of LNCaP (castration sensitive), C-42 (castration resistant), M42D, M49F (MDV3100 resistant) and PC3 (AR negative) human prostate cancer cell lines was assessed by crystal violet assay. CLU silencing was obtained by transfecting cells with short interference RNA or OGX011. Western blotting analysis was used to detect proteins expression and RT-QPCR for mRNA levels. ROS were evaluated in live cells after incubation with 2′,7′-DCFDA by FACS Canto II. Consistent with induction of proteotoxic stress, SMIP004 significantly up-regulated CLU mRNA and protein levels in prostate cancer cell lines sensitive and resistant to MDV3100. SMIP004 as well as MDV3100 were able to increase ROS production. Interestingly CLU silencing, through siRNA or OGX011, inhibited ROS while CLU overexpression, after SMIP004 and/or MDV3100, significantly induced ROS production in MDV3100 sensitive and resistant cells. Moreover SMIP004 efficiently controlled cell survival of MDV3100 sensitive and resistant prostate cancer cells but the combination with clusterin inhibitors had a synergistic effect in these cells. Interestingly, SMIP004 reduced AR variant-7, a AR splicing variant associated with abiraterone and MDV3100 resistance, in both MDV3100 sensitive and resistant cells. Clusterin plays a central role in ROS tolerance in prostate cancer cells. Clusterin inhibition in combination with SMIP004 is able to control cell survival of MDV-3100 sensitive and resistant cells also trough a modulation of oxydative stress. Citation Format: Lucia Nappi, Eliana Beraldi, Fan Zhang, Dieter Wolf, Martin Gleave. Co-targeting ROS and CLU-mediated stress response using SMIP004 (a novel inducer of ROS and cancer cell selective apoptosis) and OGX-011 in MDV3100-resistant, castrate-resistant prostate cancer. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2431. doi:10.1158/1538-7445.AM2015-2431

Impact of Enhanced Capacity to Scavenge Reactive Oxygen Species on Cold Tolerance of Tobacco

Premise of research. Reactive oxygen species (ROS) accumulate in plant tissues when the plant is exposed to stress, causing damage to cell structure and metabolism. Plants have a variety of mechanisms to prevent such damage, including a number of enzymes that scavenge ROS. The impact of specific enzymes, however, is as yet poorly understood.Methodology. The impact on plant tolerance to cold stress of enzymes involved in scavenging ROS was explored by comparing transplastomic tobacco lines overexpressing genes encoding glutathione reductase (GR), dehydroascorbate reductase (DHAR), glutathione-S-transferase (GST), and manganese superoxide dismutase, singly or in pairwise combinations, with nontransformed (NT) tobacco.Pivotal results. Chilling to 10°C resulted in less photoinhibition in lines overexpressing GR alone or in combination with GST, compared to NT tobacco, but more photoinhibition in lines overexpressing DHAR alone or in combination with GR. These differences were not, however, reflected in other indicators of stress. When chilled at 4°C, all lines showed similar damage to NT, except under relatively high photosynthetically active radiation, in which case photoinhibition was reduced in all transplastomic lines compared to NT. Growth over several weeks in a greenhouse was inhibited in the transplastomic lines when the duration included transient cool air temperatures. When optimal air temperature was maintained, growth over a similar duration was equal in transplastomics and NT tobacco.Conclusions. These experiments suggest a subtle interaction of enhanced ROS scavenging and tolerance of chilling stress.