Multiple Antioxidant Systems Research Articles

Electrical Pulse Stimulation Protects C2C12 Myotubes against Hydrogen Peroxide-Induced Cytotoxicity via Nrf2/Antioxidant Pathway.

Skeletal muscle contraction evokes numerous biochemical alterations that underpin exercise benefits. This present study aimed to elucidate the mechanism for electrical pulse stimulation (EPS)-induced antioxidant adaptation in C2C12 myotubes. We found that EPS significantly upregulated Nrf2 and a broad array of downstream antioxidant enzymes involved in multiple antioxidant systems. These effects were completely abolished by pretreatment with a ROS scavenger, N-acetylcysteine. MitoSOX-Red, CM-H2DCFDA, and EPR spectroscopy revealed a significantly higher ROS level in mitochondria and cytosol in EPS cells compared to non-stimulated cells. Seahorse and Oroboros revealed that EPS significantly increased the maximal mitochondrial oxygen consumption rate, along with an upregulated protein expression of mitochondrial complexes I/V, mitofusin-1, and mitochondrial fission factor. A post-stimulation time-course experiment demonstrated that upregulated NQO1 and GSTA2 last at least 24 h following the cessation of EPS, whereas elevated ROS declines immediately. These findings suggest an antioxidant preconditioning effect in the EPS cells. A cell viability study suggested that the EPS cells displayed 11- and 36-fold higher survival rates compared to the control cells in response to 2 and 4 mM H2O2 treatment, respectively. In summary, we found that EPS upregulated a large group of antioxidant enzymes in C2C12 myotubes via a contraction-mitochondrial-ROS-Nrf2 pathway. This antioxidant adaptation protects cells against oxidative stress-associated cytotoxicity.

A NIR-II Photoactivatable "ROS Bomb" with High-Density Cu2 O-Supported MoS2 Nanoflowers for Anticancer Therapy.

The fast conversion of hydrogen peroxide (H2 O2 )into reactive oxygen species (ROS) at tumor sites is a promising anticancer strategy by manipulating nanomedicines with near-infrared light in the second region (NIR-II). However, this strategy is greatly compromised by the powerful antioxidant capacity of tumors and the limited ROS generation rate of nanomedicines. This dilemma mainly stems from the lack of an effective synthesis method to support high-density copper-based nanocatalysts on the surface of photothermal nanomaterials. Herein, a multifunctional nanoplatform (MCPQZ) with high-density cuprous (Cu2 O) supported molybdenum disulfide (MoS2 ) nanoflowers (MC NFs) is developed for the efficient killing of tumors via a potent ROS storm by an innovative method. Under NIR-II light irradiation, the ROS intensity and maximum reaction velocity (Vmax ) produced by MC NFs are21.6and 33.8times that of the non-irradiation groupin vitro, which is much higher than most current nanomedicines. Moreover, the strong ROS storm in cancer cells isefficiently formed by MCPQZ (increased by 27.8times compared to the control), thanks to the fact that MCPQZ effectively pre-weakens the multiple antioxidant systems of cancer cells. This work provides a novel insight to solve the bottleneck of ROS-based cancer therapy.

Biochemical and Physiological Responses of Harmful Karenia mikimotoi to Algicidal Bacterium Paracoccus homiensis O-4.

Harmful algal blooms caused by Karenia mikimotoi frequently occur worldwide and severely threaten the marine environment. In this study, the biochemical and physiological responses of K. mikimotoi to the algicidal bacterium Paracoccus homiensis O-4 were investigated, and the effects on the levels of reactive oxygen species (ROS), malondialdehyde content, multiple antioxidant systems and metabolites, photosynthetic pigments, and photosynthetic index were examined. The cell-free supernatant in strain O-4 significantly inhibited K. mikimotoi cell growth. The bacterium caused the K. mikimotoi cells to activate their antioxidant defenses to mitigate ROS, and this effect was accompanied by the upregulation of intracellular antioxidant enzymes and non-enzyme systems. However, the overproduction of ROS induced lipid peroxidation and oxidative damage within K. mikimotoi cells, ultimately leading to algal death. In addition, the photosynthetic efficiency of the algal cells was significantly inhibited by O-4 and was accompanied by a reduction in photosynthetic pigments. This study indicates that O-4 inhibits K. mikimotoi through excessive oxidative stress and impaired photosynthesis. This research into the biochemical and physiological responses of K. mikimotoi to algicidal bacteria provides insights into the prophylaxis and control of harmful algal blooms via interactions between harmful algae and algicidal bacteria.

Transcriptomic and Metabolomic Measures of Oxidative Stress in the Dorsolateral Prefrontal Cortex in Schizophrenia

Oxidative stress in the brain occurs when antioxidant systems, such as reduced glutathione (GSH), are overwhelmed by pro-oxidant species, resulting in damage to fundamental cellular components and impaired neuronal functioning. Insufficient GSH is proposed as a pathogenic mechanism contributing to cortical neuronal dysfunction in schizophrenia (SZ). To investigate this possibility, we first quantified markers of the glutathione system and oxidative damage to lipids utilizing quantitative mass spectrometry in the dorsolateral prefrontal cortex (DLPFC) of SZ subjects. Next, we performed transcriptomic analysis of a gene set indexing multiple antioxidant systems in DLPFC gray matter in SZ.

Enhanced thioredoxin, glutathione and Nrf2 antioxidant systems by safflower extract and aceglutamide attenuate cerebral ischaemia/reperfusion injury.

A large number of reactive oxygen species (ROS) aggravate cerebral damage after ischaemia/reperfusion (I/R). Glutathione (GSH), thioredoxin (Trx) and nuclear factor (erythroid‐derived 2)‐like 2 (Nrf2) represent three major antioxidant systems and play vital roles in affecting each other in eliminating ROS. Identification of drugs targeting triple antioxidant systems simultaneously is vital for inhibiting oxidative damage after cerebral I/R. This study investigated the protective effect of safflower extract and aceglutamide (SAAG) against cerebral I/R injury through modulating multiple antioxidant systems of GSH, Trx and Nrf2 and identified each role of its component acegluatminde (AG) and safflower extract (SA) on these systems. Safflower extract and aceglutamide and its two components decreased neurological deficit scores, infarction rate, apoptosis and oxidative damage after cerebral I/R while enhanced cell viability, decreased reactive oxygen species and nitric oxide level in H2O2‐induced PC12 cell model. Importantly, compared to its two components, SAAG demonstrated more effective enhancement of GSH, Nrf2 and Trx systems and a better protection against cerebral I/R injury. The enhanced antioxidant systems prevented ASK1 activation and suppressed subsequent p38 and JNK cascade‐mediated apoptosis. Moreover, inhibition of Trx and Nrf2 systems by auranofin and ML385 abolished SAAG‐mediated protection, respectively. Thus, enhanced triple systems by SAAG played a better protective role than those by SA or AG via inhibition of ASK1 cascades. This research provided evidence for the necessity of combination drugs from the perspective of multiple antioxidant systems. Furthermore, it also offers references for the study of combination drugs and inspires novel treatments for ischaemic stroke.

The Parallel Molecular Adaptations to the Antarctic Cold Environment in Two Psychrophilic Green Algae.

Psychrophilic green algae from independent phylogenetic lines thrive in the polar extreme environments, but the hypothesis that their psychrophilic characteristics appeared through parallel routes of molecular evolution remains untested. The recent surge of transcriptome data enables large-scale evolutionary analyses to investigate the genetic basis for the adaptations to the Antarctic extreme environment, and the identification of the selective forces that drive molecular evolution is the foundation to understand the strategies of cold adaptation. Here, we conducted transcriptome sequencing of two Antarctic psychrophilic green algae (Chlamydomonas sp. ICE-L and Tetrabaena socialis) and performed positive selection and convergent substitution analyses to investigate their molecular convergence and adaptive strategies against extreme cold conditions. Our results revealed considerable shared positively selected genes and significant evidence of molecular convergence in two Antarctic psychrophilic algae. Significant evidence of positive selection and convergent substitution were detected in genes associated with photosynthetic machinery, multiple antioxidant systems, and several crucial translation elements in Antarctic psychrophilic algae. Our study reveals that the psychrophilic algae possess more stable photosynthetic apparatus and multiple protective mechanisms and provides new clues of parallel adaptive evolution in Antarctic psychrophilic green algae.

PO-034 Inhibition of lung carcinoma growth and pulmonary metastasis with DIMATE as single agent and in combination with cisplatin

IntroductionAberrant cell proliferation in NSCLC causes an aberrant redox state that leads to the production of toxic reactive species and aldehydes. To keep oxidative stress until a threshold, above which oxidative damage can be detrimental to cell viability, cancer cells must actively upregulate multiple antioxidant systems. The aldehyde dehydrogenase (ALDH) gene superfamily encodes enzymes that are critical for certain life processes and detoxification of numerous endogenous and exogenous aldehyde substrates, including pharmaceuticals and environmental pollutants.Material and methodsIn this study, a meta-analysis was conducted based on multiple microarray data from The Cancer Genome Atlas (TCGA) and gene expression omnibus (GEO) repositories, spanning lung adenocarcinoma and lung squamous cell carcinoma datasets. Twenty-six NSCLC cell lines with different oncogenic driver alterations were used to analyse the molecular and cellular consequences of ALDHs inhibition. Preclinical studies with orthotopic xenografts of NSCLC and lung metastatic breast cancer were performed to evaluate the effect of the inhibition of ALDH class 1 and class3 activity on tumour growth.Results and discussionsHere, we found that increased expression of aldehyde dehydrogenase isoenzymes ALDH1A1, ALDH1A3 and ALDH3A1 in human NSCLC tumours has a strong impact on chemotherapy resistance and patient overall survival, correlating with poor prognosis. We showed that inhibition of class 1 and class 3 ALDH activity with the novel irreversible ALDH1/3 inhibitor DIMATE suppresses tumour growth in orthotopic human lung cancer xenograft model and inhibits lung metastasis of human breast cancer in athymic nude mice. Accumulation of HNE-protein adducts and depletion of intracellular GSH are main responsible of DIMATE-induced cell death. Consistently, we found that alteration of tumour redox balance further enhances sensitivity of NSCLC cells to DIMATE. Finally, we demonstrate that the combination of DIMATE with Cisplatin-induced ROS generation in an orthotopic lung cancer model can significantly enhance the cytotoxicity of these two drugs in NSCLC cells with a synergistic promotion of cell death and marginal systemic toxicity in animals.ConclusionTargeting the detoxification machinery of ALDHs constitutes a novel therapeutic avenue for NSCLC. Patients with increased expression of ALDH1 or ALDH3 might greatly benefit from a combination therapy that include drugs interfering with the activity of these enzymes to overcome patient-specific drug resistance.

On the Redox Profile of B- Cell Terminal Differentiation and Multiple Myeloma: New Insights and Therapeutic Opportunities

Redox homeostasis is fundamental for normal cellular functioning and is maintained by the net physiologic balance between production and removal of ROS. Redox signaling has been shown to coordinate the global signal transduction pattern critical for the control of key cellular processes including differentiation and tumorogenesis. In the present study, we review the systematic expression of ROS-producing and antioxidant genes and we draw up a full redox portrait of B cells all the way throughout B- cells expansion and differentiation and in malignant plasma cells. Our data firmly established that B-cells terminal differentiation entails drastic reshaping of the redox profile and underscore the stark transcriptional divide between B cells and plasma cells compartments with a major contribution of the Thioredoxin-Glutathione system in latter one. Furthermore, we advanced significant evidence that the most aggressive Multiple Myeloma cells (MMCs) witness increased expression of ROS producing genes and actively upregulated multiple antioxidant systems, which likely afforded high cytoprotective capacities and compromise chemotherapy efficacy. More importantly, we describe a transcriptional redox signature that enables the demarcation of good versus bad prognosis of MM patients and hold promise for robust molecular signature that could predict responsiveness. Finally, our data pinpointed the Thioredoxin-Glutathione system as actionable targets to circumvent drug resistance. Using Human Myeloma cell lines and primary cultures of MMCs, we validated Thioredoxin-Glutathione system as new critical, key functional node in the oncogenic network of MMCs whose depletion kill tumor cells and improve the response rate. We provided herein a preclinical data, which warrants further clinical investigation for the potential use of redox-modulators as a novel MM treatment strategy. DisclosuresNo relevant conflicts of interest to declare.

Cross-talk between two antioxidants, thioredoxin reductase and heme oxygenase-1, and therapeutic implications for multiple myeloma

Multiple myeloma (MM) is characterized by an accumulation of abnormal clonal plasma cells in the bone marrow. Despite recent advancements in anti-myeloma therapies, MM remains an incurable disease. Antioxidant molecules are upregulated in many cancers, correlating with tumor proliferation, survival, and chemoresistance and therefore, have been suggested as potential therapeutic targets. This study investigated the cross-talk between two antioxidant molecules, thioredoxin reductase (TrxR) and heme oxygenase-1 (HO-1), and their therapeutic implications in MM. We found that although auranofin, a TrxR inhibitor, significantly inhibited TrxR activity by more than 50% at lower concentrations, myeloma cell proliferation was only inhibited at higher concentrations of auranofin. Inhibition of TrxR using lower auranofin concentrations induced HO-1 protein expression in myeloma cells. Using a sub-lethal concentration of auranofin to inhibit TrxR activity in conjunction with HO-1 inhibition significantly decreased myeloma cell growth and induced apoptosis. TrxR was shown to regulate HO-1 via the Nrf2 signaling pathway in a ROS-dependent manner. Increased HO-1 mRNA levels were observed in bortezomib-resistant myeloma cells compared to parent cells and HO-1 inhibition restored the sensitivity to bortezomib in bortezomib-resistant myeloma cells. These findings indicate that concurrent inhibition of HO-1 with either a TrxR inhibitor or with bortezomib would improve therapeutic outcomes in MM patients. Hence, our findings further support the need to target multiple antioxidant systems alone or in combination with other therapeutics to improve therapeutic outcomes in MM patients.

Increasing levels of serum antioxidant status, total antioxidant power, in systemic sclerosis

Oxidative stress is one of the important factors that contribute to tissue damage in systemic sclerosis (SSc). Since the physiological response to oxidative stress is regulated by multiple antioxidant systems, it is important to measure quantitatively the total antioxidant capacity in the biological specimens. To determine the clinical significance of total antioxidant power (TAP) in SSc, we investigated the prevalence and clinical correlation of serum TAP levels in SSc patients. Serum TAP levels were examined in 49 patients with SSc by colorimetric microplate assay. The assay measures the total abilities for reducing Cu++ into Cu+. Clinical evaluation including medical history, physical examination, and laboratory tests were conducted for all SSc patients. Serum TAP levels were significantly elevated in SSc patients compared to normal controls (p < 0.01). When values higher than the mean + 2SD of the control serum samples were considered to be elevated, TAP levels were elevated in 24% of total SSc patients, with 26% of diffuse cutaneous SSc patients and 23% of limited cutaneous SSc patients. Serum TAP levels were correlated positively with C-reacting protein (r = 0.35, p ≤ 0.05). However, no other significant correlation was observed between serum TAP levels and clinical features in SSc patients. These results suggested that oxidative stress is enhanced in SSc patients, and serum TAP levels increase as an indicator of the global response to oxidative stress.

Selenoproteins and Protection against Oxidative Stress: Selenoprotein N as a Novel Player at the Crossroads of Redox Signaling and Calcium Homeostasis

Healthy cells continually produce low levels of reactive oxygen species (ROS), which are buffered by multiple antioxidant systems. Imbalance between ROS production and elimination results in oxidative stress, which has been implicated in aging and in numerous human diseases, including cancer and diabetes. Selenoproteins are a family of proteins that contain the amino acid selenocysteine, encoded by an in-frame UGA. Those selenoproteins whose function is identified are catalytically active in redox processes, representing one of the main enzymatic antioxidant systems and important mediators of the beneficial role of selenium in human health. Nevertheless, the function of most selenoproteins remains unknown; this included Selenoprotein N (SelN), the only selenoprotein directly associated with a human genetic disease. Mutations of the SelN gene cause SEPN1-related myopathy, a particular early-onset muscle disorder. Recent studies have identified SelN as a key protein in cell protection against oxidative stress and redox-related calcium homeostasis. Furthermore, an effective ex vivo treatment of SelN deficiency has been identified, paving the way to a clinical therapy. In this review we discuss the physiological and pathophysiological role of SelN and the interest of SEPN1-related myopathy as a model paradigm to understand and target therapeutically other selenoproteins involved in human health and disease.

Environmental Stimulus Package: Potential for a Rising Oxidative Deficit

A close relationship exists between the multiple systems in the body and the gradual exposure to the environmental influences of oxidative stress, such as airborne particulate matter, pesticides, diet and lifestyle. Over time, exposure to exogenous sources of oxidative stress can ultimately impair both tissue and cellular function and lead to cellular senescence, apoptosis, and the destruction of nuclear chromatin. The effects of oxidative stress from the environment may be muted in some individuals if sufficient anti-oxidant defenses are in place. However, in others, comprised defenses such as those that can occur with immune system dysfunction, can lead to progressive damage in genetic coding and mitochondrial DNA that have been associated with signaling pathway errors and tumorigenesis. Interestingly, “multiple hits” by environmental toxins may be required to lead to system dysfunction or tumor growth. For example, a number of studies have observed that an accumulation of gene mutations with increased age may be necessary to eventually lead to cancers involving the breast or the gastrointestinal tract. Furthermore, the exposure to exogenous agents that may generate the release of reactive oxygen species also may initiate a critical cascade of cell injury. The occurrence of genetic mutations from the initial release of reactive oxygen species can then lead to polymorphisms in key enzymes such as glutathione S-transferase and cytochrome p450 that are vital to protect cells and tissues against oxidative stress. As a result of the loss of these anti-oxidant pathways, further accumulated tissue damage can ensue and the risk of developing significant illness increases further. Given the intimate relationship between the body and its susceptibility to exogenous sources of oxidative stress, we have highlighted a number of novel studies in this issue of Oxidative Medicine and Cellular Longevity that examine specific cellular and tissue responses to endogenous agents and the broad anti-oxidant systems that can mitigate injury during normal physiology and disease states. Kovacic and Somanathan set the stage for this issue with their opinion paper that describes the biology of a hallucinogenic agent that was an integral part of religious ceremonies by early North American natives and its use remains in our current society, namely mescaline. Their work provides new understanding for the cellular signaling of this agent in the nervous system, its role in structure function relations, and its ties to the hallucinogen psilocybin. In his review article, Flora broadens this perspective in regards to xenobiotics with metal and metalloid exposure. The biological properties of several agents that can lead to human illness are discussed that include copper, cobalt, and arsenic as well as the multiple anti-oxidant systems that can be activated, such as carotenoids, enzymes, hormones, phenolics, minerals, and vitamins. Interestingly, anti-oxidant systems also may play a significant role to prevent toxicity of chemotherapeutic agents. Al-Yahya et al. demonstrate that a naturally occurring branched-chain complex polysaccharide termed Gum Arabic can neutralize acrolein, a reactive metabolite of cyclophosphamide and block bladder toxicity from reactive oxygen species that may provide new direction for chemotherapeutic agents to enhance efficacy but limit toxicity. The ability to block cellular injury during periods of toxic elevated reactive oxygen species release also may be extended to a number systems throughout the body. Santo et al. show that ascorbic acid may be a powerful cytoprotectant in highly sensitive regions of the central nervous system during epilepsy and oxidative stress. Furthermore, in the paper by Mahapatra et al. that examines the effects of the exogenous toxin nicotine on immune cells, extracts from the plant Ocimum gratissimum were shown to have high flavonoid and phenolic content that may account for the ability of this agent to reduce super oxide anion generation, lipid peroxidation, and prevent cytotoxicity in immune cell peritoneal macrophages, suggesting that even the inflammatory effects of tobacco smoke that contains at least sixty known carcinogens may be reduced with appropriate anti-oxidant therapy. The efficacy of anti-oxidant therapy is brought to clinical consideration by Tripathi et al. in their paper. These investigators illustrate that administration of L-arginine, which has anti-apoptotic properties and can improve endothelial function, was able to lower serum cholesterol, increase superoxide dismutase function, and enhance the levels of total thiols in patients with cardiac ischemia, suggesting that chronic therapy with L-arginine in these patients may prevent the detrimental

W1865 N-Acetyl Cysteine Ameliorates Liver Injury in Patients with Erythropoietic Protoporhyria

mice. mRNA expression of Nrf2 was increased by 80% (p<0.02 vs. nTg) while mRNA expression of its cytosolic repressor protein, Keap1, was increased by 180% (p<0.006 vs. nTg). Expression of the antioxidant enzymes CAT, HO-1, GPx, GST and TRX were significantly increased in liver of the Tg mice. Expression of SOD 1 and SOD 2 was not increased in Tg mice. Conclusion: Overexpression of CYP2E1 in hepatocytes in the setting of a high fat diet increases ER stress which leads to increased expression of Nrf2 as well as multiple antioxidant systems regulated by Nrf2. Nevertheless, markers of oxidative stress are increased in CYP2E1 Tg mice indicating insufficient overall antioxidant response. Increased expression of Keap1 in Tg mice may limit the ability of Nrf2 to translocate to the nucleus thereby limiting the antioxidant response and contributing to increased oxidative liver injury.

Phospholipid hydroperoxide glutathione peroxidase plays a role in protecting cancer cells from docosahexaenoic acid–induced cytotoxicity

Docosahexaenoic acid (DHA; 22:6, n-3) is known to exert cytotoxic effects against various types of tumors via lipid peroxidation. Whereas several enzymes influence the response of cells to oxidative stress, only one enzyme, phospholipid hydroperoxide glutathione peroxidase (GPx-4), directly reduces lipid hydroperoxides in mammalian cells. The present study was designed to examine the involvement of GPx-4 in determining the effects of DHA addition to various human cancer cell lines. Although baseline levels of GPx-4 did not correlate with the relative sensitivity of human cancer cell lines to DHA, DHA reduced the level of protein expression of GPx-4 by at least 50% in all six lines. Knockdown of GPx-4 by small interfering RNA technique in a human ovarian cancer cell line significantly enhanced the cytotoxic effect of DHA in a time- and concentration-dependent manner. This cytotoxic effect of DHA was reversed by pretreatment with vitamin E, suggesting that the enhanced toxicity of GPx-4 knockdown is due to changes in the ability of the cells to handle oxidative stress. Neither baseline superoxide dismutase-1 nor catalase expression correlated with the relative sensitivity of the cells to DHA treatment. These results illustrate that susceptibility to the oxidative stress imposed by DHA, and possibly other therapeutic agents, is due to complex interactions among multiple antioxidant systems. The modulation of GPx-4 levels by DHA administration is of potential importance and may influence the cellular response to other oxidant stresses.