Regulation Of Reactive Oxygen Species Research Articles

An Enzyme Mimicking Dendritic Platinum–Iron Oxide Catalyzes the Production of Reactive Oxygen Species

Creatine catalase (CAT), superoxide dismutase (SOD), and NADPH oxidase (NOX) are natural enzyme molecules that play a crucial role in regulating reactive oxygen species (ROS) in biological systems. They maintain life activities and eliminate pathogens by catalyzing various biochemical reactions. However, natural enzymes have some drawbacks in ROS control; they may lose activity under certain environmental conditions, such as high temperatures, extreme pH values, or the presence of organic solvents, which affects their stability and reliability in different applications. The construction of artificial nanozymes is an emerging technology that could probably solve the problems existing in natural enzymes. This study introduces a type of dendritic platinum–iron oxide (DPIO) nanozyme. The unique dendritic structure of this DPIO nanozyme provides a high surface area-to-volume ratio, and the addition of a platinum layer on the surface offers stability, thereby effectively enhancing the catalytic efficiency of producing reactive oxygen species (ROS). The combination of iron-based Fenton reactions and platinum-based Fenton-like reactions in this DPIO nanozyme drastically improves ROS catalytic efficiency. This artificial nanozyme has a high level of biosafety and displays no cytotoxicity. The development of DPIO nanozymes marks a significant advancement in the technology of artificial nanozymes.

The Hippo Signaling Pathway, Reactive Oxygen Species Production, and Oxidative Stress: A Two-Way Traffic Regulation.

The Hippo signaling pathway is recognized for its significant role in cell differentiation, proliferation, survival, and tissue regeneration. Recently, the Hippo signaling pathway was also found to be associated with oxidative stress and reactive oxygen species (ROS) regulation, which are important in the regulation of cell survival. Studies indicate a correlation between components of the Hippo signaling pathway, including MST1, YAP, and TAZ, and the generation of ROS. On the other hand, ROS and oxidative stress can activate key components of the Hippo signaling pathway. For example, ROS production activates MST1, which subsequently phosphorylates FOXO3, leading to apoptotic cell death. ROS was also found to regulate YAP, in addition to MST1/2. Oxidative stress and ROS formation can impair lipids, proteins, and DNA, leading to many disorders, including aging, neurodegeneration, atherosclerosis, and diabetes. Consequently, understanding the interplay between the Hippo signaling pathway, ROS, and oxidative stress is crucial for developing future disease management strategies. This paper aimed to review the association between the Hippo signaling pathway, regulation of ROS production, and oxidative stress to provide beneficial information in understanding cell function and pathological processes.

RNA editing-induced structural and functional adaptations of NAD9 in Triticum aestivum under drought stress.

Mitochondria are essential organelles in eukaryotic cells, producing ATP through the electron transport chain to supply energy for cellular activities. Beyond energy production, mitochondria play crucial roles in cellular signaling, stress responses, and the regulation of reactive oxygen species. In plants, mitochondria are one of the keys to responding to environmental stresses which can significantly affect crop productivity, particularly in crops like wheat. RNA editing, a post-transcriptional RNA modification process in mitochondria, is linked to regulating these stress responses. This study explores RNA editing patterns in the nad9 gene of wheat drought-tolerant (Giza168) and drought-sensitive (Gemmiza10) wheat cultivars under drought stress to understand plant adaptation mechanisms. RNA-seq data for these cultivars were analyzed using CLC Genomic Workbench to identify RNA editing sites in the nad9 gene, examining subsequent amino acid changes and predicting secondary structure modifications. These RNA editing sites were validated using qRT-PCR on drought-treated seedlings at 0, 2, and 12 hours post-treatment. Protein models were generated using AlphaFold, with functional predictions and structure verification conducted using various bioinformatics tools to investigate the effect of RNA editing on protein level. The results showed significant RNA editing events, especially C-to-T conversions, in the nad9 gene across different drought exposure times. Giza168 had 22 editing sites, while Gemmiza10 had 19, with several showing significant differences between control and stress conditions. RNA editing influenced the NAD9 protein's secondary structure, particularly beta sheets, and 3D modeling highlighted the structural impacts of these edits. The N-terminal region of NAD9 contained important regulatory motifs, suggesting a complex regulatory environment. This study reveals key editing sites that differ between drought-tolerant and sensitive wheat cultivars, impacting NAD9 protein structures and highlighting the role of RNA editing in enhancing drought resilience. Additionally, the study suggests potential regulatory mechanisms, including phosphorylation and ubiquitination that influence mitochondrial stability and function.

Amoeba-Inspired Soft Robot for Integrated Tumor/Infection Therapy and Painless Postoperative Drainage.

Tumor recurrence and wound infection are devastating complications of wide excision surgery for melanoma, and deep postoperative wound drainage typically increases pain. An amoeba-inspired magnetic soft robot (ASR) with switchable dormant and active phases is developed to address the aforementioned challenges. The dormant ASR supports wounds through its solid-like elasticity and regulates reactive oxygen species (ROS) levels bidirectionally, promoting healing in infected wounds and eliminating residual tumors. It solves the challenge caused by the contradictory need for ROS scavenging in wound healing and ROS amplification in tumor/infection management. The active ASR removes absorbed wound exudate by crawling out from irregular wounds; interestingly, this crawling motion prevents damage to fragile tissues and alleviates wound pain via "non-direct friction." More importantly, ASR switches different states in response to an alternating magnetic field owing to its magnetothermal properties, and this process also exerts synergistic antitumor and bacteriostatic effects. Due to the appropriate mechanical structure (cohesive force) of ASR, the content of magnetic nanoparticles required to drive the ASR is ten-fold lower than that of conventional magnetic soft robots, enabling in vivo degradation. These outcomes highlight the vantage of the ASR for treating post-tumor excision wounds and underscore their potential for clinical application.

Chromone Derivatives as a Novel NOX4 Inhibitor: Design, Synthesis, and Regulation of ROS in Renal Fibroblast.

Nicotinamide adenine dinucleotide phosphate oxidase 4 (NOX4) has emerged as a promising target for developing drugs to tackle renal fibrosis. In this study, a series of chromone derivatives were designed and synthesized. Additionally, we established a NOX4 overexpression model using the NRK-49F rat renal fibroblasts cell line and identified compound 14m as highly active through the assessment of intracellular reactive oxygen species (ROS) levels in this model. The drug affinity responsive target stability (DARTS) assay illuminated the robust binding stability of 14m with NOX4. Mechanistic studies further substantiated its efficacy in ameliorating fibrosis and inflammation. This investigation positions 14m as a noteworthy NOX4 inhibitor, shedding light on its regulatory role in renal fibroblasts. Importantly, it diversifies the structural landscape of NOX4 inhibitors, offering novel lead compounds for future development.

Orexin-A Attenuates the Inflammatory Response in Sepsis-Associated Encephalopathy by Modulating Oxidative Stress and Inhibiting the ERK/NF-κB Signaling Pathway in Microglia and Astrocytes.

Oxidative stress-induced inflammation is a major pathogenic mechanism in sepsis-associated encephalopathy (SAE). We hypothesized that regulation of reactive oxygen species (ROS) by the neuropeptide orexin-A could prevent SAE-induced oxidative stress and inflammation. Therefore, the aim of this study was to investigate the effects of orexin-A on oxidative stress and inflammation in SAE in mice. Adult male mice were treated with orexin-A (250 μg/kg, intranasal administration) to establish a cecal ligation perforation (CLP) model. We performed behavioral tests, observed neuronal damage in the hippocampal region, measured the levels of ROS, NOX2, and observed the structure of mitochondria by transmission electron microscopy. We then examined the inflammatory factors TNF-α and IL-1β, the activation of microglia and astrocytes, the expression of ERK/NF-κB, C3, and S100A10, and the presence of A1 type astrocytes and A2 type astrocytes. Orexin-A treatment improved cognitive performance in CLP-induced SAE mice, attenuated neuronal apoptosis in the hippocampal region, ameliorated ROS levels and the extent of mitochondrial damage, and reduced protein expression of NOX2 in hippocampal tissue. In addition, orexin-A treatment significantly reduced microglia and astrocyte activation, inhibited the levels of P-ERK and NF-κB, and reduced the release of IL-1β and TNF-α, which were significantly increased after CLP. Finally, Orexin-A treatment significantly decreased the number of C3/glial fibrillary acidic protein (GFAP)-positive cells and increased the number of S100A10/GFAP-positive cells. Our data suggest that orexin-A reduces ROS expression by inhibiting CLP-induced NOX2 production, thereby attenuating mitochondrial damage and neuronal apoptosis. Its inhibition of microglial and A1-type astrocyte activation and inflammation was associated with the ERK/NF-κB pathway. These suggest that orexin-A may reduce cognitive impairment in SAE by reducing oxidative stress-induced inflammation.

Demystifying the management of cancer through smart nano-biomedicine via regulation of reactive oxygen species.

Advancements in therapeutic strategies and combinatorial approaches for cancer management have led to the majority of cancers in the initial stages to be regarded as treatable and curable. However, certain high-grade cancers in the initial stages are still regarded as chronic and difficult to manage, requiring novel therapeutic strategies. In this era of targeted and precision therapy, novel strategies for targeted delivery of drug and synergistic therapies, integrating nanotherapeutics, polymeric materials, and modulation of the tumor microenvironment are being developed. One such strategy is the study and utilization of smart-nano biomedicine, which refers to stimuli-responsive polymeric materials integrated with the anti-cancer drug that can modulate the reactive oxygen species (ROS) in the tumor microenvironment or can be ROS responsive for the mitigation as well as management of various cancers. The article explores in detail the ROS, its types, and sources; the antioxidant system, including scavengers and their role in cancer; the ROS-responsive targeted polymeric materials, including synergistic therapies for the treatment of cancer via modulating the ROS in the tumor microenvironment, involving therapeutic strategies promoting cancer cell death; and the current landscape and future prospects.

Seawater-induced Salinity Enhances Antioxidant Capacity by Modulating Morpho-physiological and Biochemical Responses in Catharanthus roseus

Salt stress impedes plant growth and development due to several factors, including the generation of cellular oxidative stressors. This study aimed to assess the impacts of seawater-induced salinity on the plant development, physio-biochemical responses, and antioxidant capacity of Catharanthus roseus grown in a variety of seawater (4, 8, and 12 dS/m) for varying durations (60, 90, and 120 days). The experiment was laid out in a randomized complete block design with five replications. The results demonstrated that C. roseus successfully endured moderate salinity (8 dS/m) by maintaining plant height, number of leaves, branches, relative water content, and chlorophyll content with a minimum drop in dry biomass (25%) in a time- and dose-dependent approach. Furthermore, greater proline and soluble sugar contents suggested that C. roseus possessed enhanced osmoprotective capabilities to counteract osmotic stress caused by salinity. Conversely, all growth indicators decreased significantly at high salinity (12 dS/m). Increased levels of antioxidant enzyme activity catalase and ascorbate peroxidase, phenol and flavonoid, 2,2-diphenyl-1-picrylhydrazyl and 2,2-azino-bis-3-ethylbenzothiazoline-6-sulphonic acid indicate a coordinated function for antioxidant components in regulating reactive oxygen species (ROS) at low (4 dS/m) and moderate (8 dS/m) salinities. In contrast, excessive salinity (12 dS/m) led to a burst of ROS, as seen by elevated levels of hydrogen peroxide, malondialdehyde, and electrolyte leakage that greatly reduced total dry matter (72%), especially on days 120. The ion studies on plants subjected to salinity revealed that most Na+ remained in the roots. In contrast, most K+, Ca2+, and Mg2+ are deposited more firmly in the leaves than in the roots. The findings imply that C. roseus may tolerate moderate salinity (8 dS/m) owing to its enhanced antioxidant defense system and osmolytes, which trigger antioxidant enzymes and maintain ionic balance.

Orchestrating ROS regulation: coordinated post-translational modification switches in NADPH oxidases.

Reactive oxygen species (ROS) are among the most important signaling molecules, playing a significant role in plant growth, development, and responses to various environmental stresses. Respiratory burst oxidase homologs (RBOHs) are key enzymes in ROS production. Plants tightly regulate the activation and deactivation of RBOHs through various post-translational modifications (PTMs), including phosphorylation, ubiquitination, S-nitrosylation, and persulfidation. These PTMs fine-tune ROS production, ensuring normal plant growth and development while facilitating rapid responses to abiotic and biotic stresses. This review discusses the effects of different PTMs on RBOH function and their biological relevance. Additionally, we examine the evolutionary conservation of PTM sites and emphasize the complex interplay between multiple PTMs regulating RBOHs.

Collaboration in Contradiction: Self-Adaptive Synergistic ROS Generation and Scavenge Balancing Strategies Used for the Infected Wounds Treatment.

The rational utilization of ROS is key to treating infected wounds. Exogenous ROS can destroy bacterial structures, quickly kill bacteria, and inhibit secondary infections. However, excess ROS at the wound will cause a secondary inflammatory response. Acute infections exacerbate this damage by increasing endogenous ROS, complicating the maintenance of ROS homeostasis. Therefore, regulating the balance of ROS production and scavenging in wounds has emerged as a promising strategy for wound treatment. Conventional ROS balancing platforms are mostly based on the " all for one" strategy of functional superposition and lack self-adaptability and integration. To subvert this conventional strategy, this study proposes a "one for all" self-adaptive integrated photodynamic therapy (PDT)-antioxidant model to actively regulate the ROS balance. A gelatin-hyaluronic acid hydrogel embedded with Se-modified cerium dioxide nanoparticles (Gel-HA-Se@CeO2 NPs) is designed for treating infected wounds. The Se@CeO2 NPs serve both as nanoenzymes and photosensitizers(PS). As nanoenzymes, they exhibit catalase and superoxide dismutase activities, converting hydrogen peroxide and superoxide anions into oxygen. As a PS, it synergizes with oxygen under NIR irradiation to rapidly produce singlet oxygen. Additionally, Se modification enhances the PDT effects by disrupting bacterial antioxidant systems. In vitro and in vivo experiments revealed that the ROS balance platform polarizes M1-type macrophages to M2-type macrophages, altering the wound microenvironment from proinflammatory to prohealing. RNA sequencing revealed that this hydrogel accelerated the reconstruction of the vascular network of the wound by activating the PI3K/AKT pathway and increasing VEGF secretion.This strategy is believed to be beneficial not only for infected wounds but also for treating other conditions that involve the regulation of reactive oxygen species, such as tumors and bacterial infections.

Neutrophils with low production of reactive oxygen species are activated during immune priming and promote development of arthritis

Rheumatoid arthritis (RA) is an inflammatory autoimmune disease mediated by immune cell dysfunction for which there is no universally effective prevention and treatment strategy. As primary effector cells, neutrophils are important in the inflammatory joint attack during the development of RA. Here, we used single-cell sequencing technology to thoroughly analyze the phenotypic characteristics of bone marrow-derived neutrophils in type II collagen (COL2)-induced arthritis (CIA) models, including mice primed and boosted with COL2. We identified a subpopulation of neutrophils with high expression of neutrophil cytoplasmic factor 1 (NCF1) in primed mice, accompanied by a characteristic reactive oxygen species (ROS) response, and a decrease in Ncf1 expression in boosted mice with the onset of arthritis. Furthermore, we found that after ROS reduction, arthritis occurred in primed mice but was attenuated in boosted mice. This bidirectional effect of ROS suggested a protective role of ROS during immune priming. Mechanistically, we combined functional assays and metabolomics identifying Ncf1-deficient neutrophils with enhanced migration, chemotactic receptor CXCR2 expression, inflammatory cytokine secretion, and Th1/Th17 differentiation. This alteration was mainly due to the metabolic reprogramming of Ncf1-deficient neutrophils from an energy supply pathway dominated by gluconeogenesis to an inflammatory immune pathway associated with the metabolism of histidine, glycine, serine, and threonine signaling, which in turn induced arthritis. In conclusion, we have systematically identified the functional and inflammatory phenotypic characteristics of neutrophils under ROS regulation, which provides a theoretical basis for understanding the pathogenesis of RA, to further improve prevention strategies and identify novel therapeutic targets.

Precisely Engineering a ROS‐Regulatable Decellularized Matrix to Rejuvenate Endogenous Repair for Heart Valve Remodeling in Diabetic Cohort

AbstractThe reconstruction of a heart valve through in situ tissue engineering remains a formidable challenge, particularly for patients with diabetes mellitus, because the pathophysiological alterations associated with diabetes substantially impair the cardiovascular system's intrinsic repair capacity. In this study, reactive oxygen species (ROS) regulation are integrated into the fabrication of pro‐endothelialization interfaces to counteract the adverse repair environment. Specifically, a heparin‐mimicking alginate‐derived glycopeptide and the natural ROS scavenger melanin are modified onto the surface of a decellularized extracellular matrix (dECM). This tailored interface significantly enhances endothelial cell (EC) adhesion while reducing platelet adhesion. The incorporation of melanin effectively suppresses ROS elevation in ECs and macrophages under hyperglycemic conditions. Consequently, this intervention promotes EC rejuvenation by enhancing proliferation, migration, and anti‐apoptotic capabilities, while concurrently attenuating the release of inflammatory and pro‐fibrotic factors by macrophages. The dECM is intravascularly implanted in a diabetic rabbit model after being fabricated into a covered stent, demonstrating favorable remodeling characteristics such as enhanced endothelialization and reduced fibrotic deposition. This scaffold design, specifically tailored to the pathological conditions of diabetes, offers a precise biomaterial strategy for in situ heart valve tissue engineering.

Dose-Response Effect of Various Concentrations of Cl-Containing Water-Soluble Derivatives of C60 Fullerenes on a Selective Regulation of Gene Expression in Human Embryonic Lung Fibroblasts (HELF).

The new synthesized water-soluble derivatives of C60 fullerenes are of a great interest to researchers since they can potentially be promising materials for drug delivery, bioimaging, biosonding, and tissue engineering. Surface functionalization of fullerene derivatives changes their chemical and physical characteristics, increasing their solubility and suitability for different biological systems applications, however, any changes in functionalized fullerenes can modulate their cytotoxicity and antioxidant properties. The toxic or protective effect of fullerene derivatives on cells is realized through the activation or inhibition of genes and proteins of key signaling pathways in cells responsible for regulation of cellular reactive oxygen species (ROS) level, proliferation, and apoptosis. The 3-[4,5-dimethylthiazol-2-yl]-2,5 diphenyl tetrazolium bromide (MTT) assay was used to assess cells viability. Flow cytometry analyses was applied to measure proteins levels in human embryonic lung fibroblasts (HELF) cells. HELF is a standard, stable and well described human cell line that can be passaged many times. Quantitation of ROS was assessed using H2DCFH-DA. Fluorescence images were obtained using microscopy. Expression of BCL2, CCND1, CDKN2A, BRCA1, BAX, NFKB1, NOX4, NRF2, TBP (reference gene) was analyzed using real-time Polymerase chain reaction (PCR). We found that high and low concentrations of fullerene C60 derivatives with the five residues of potassium salt of 6-(3-phenylpropanamido)hexanoic (F1) or 6-(2-(thiophen-2-yl)acetamido)hexanoic (F2) acid and a chlorine atom attached directly to the cage cause diametrically opposite activation of genes and proteins of key signaling pathways regulating the level of oxidative stress and apoptosis in HELF. High concentrations of F1 and F2 have a genotoxic effect, causing NADPH oxidase 4 (NOX4) expression activation in 24-72 hours (2-4 fold increase), ROS synthesis induction (increase by 30-40%), DNA damage and breaks (2-2.5 fold 8-oxodG level increases), and activation of nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) (by 40-80%) against the background of reduced NF-E2-related factor 2 (NRF2) expression (by 20-45%). Low concentrations of F1 and F2 produced a cytoprotective effect: in 24-72 hours they reduce the oxidative DNA damage (by 20-40%), decrease the number of double-strand DNA breaks (by 20-30%), increase the level of anti-apoptotic proteins and enhance the antioxidant response activating the NRF2 expression (NRF2 gene expression increases 1.5-2.3 fold, phosphorylated form of the NRF2 protein increases 2-3 fold). Obtained results show that in low doses studied fullrens may serve as perspective DNA protectors against the damaging genotoxic factors.

Differentiating Reactive Oxygen Species with DNA Framework Monitors.

The lifespan, oxidizing properties, bonding behaviors, and reactivity of reactive oxygen species (ROS) produced during photocatalytic activation can vary significantly due to the differences in electron configurations of ROS, which are dependent on their generation mechanisms: energy transfer or charge transfer. Hence, identifying and differentiating ROS of different mechanisms can improve our understanding of redox reactions and related diseases, providing a basis for the prevention and treatment of related diseases. Here, we have developed a DNA framework monitor (DFM) based on dynamic DNA structural changes to effectively distinguish the two types of ROS produced in photocatalytic activation of O2. This DFM provides a visualization tool for observing the reaction kinetics of ROS with DNA, not only distinguishing two types of ROS with different mechanisms but also serving as a universal system for evaluating the efficacy and performance of nanomaterials for ROS regulation.

8801 Towards Safe and Efficacious Medical Therapy for Patients with Clinically Non-Functioning Pituitary Tumors

Abstract Disclosure: D. Zhang: None. M. Bergsneider: None. W. Kim: None. M.B. Wang: None. H. Vinters: None. A.P. Heaney: None. Clinically non-functioning pituitary tumors (CNFTs) account for one-third of all pituitary adenomas. They do not cause clinical and/or biochemical evidence of tumor-related hormone hypersecretion, grow insidiously and typically present with mass effect symptoms such as headache and visual field deficits. Surgical resection is the current standard of care for CNFTs but complete resection is infrequently achieved due to their size and invariable invasion of locally adjacent structures. CNFT remnant tumor regrowth rates approach 50% and these patients may need repeat surgery and/or radiotherapy (RT). The latter is quite effective in achieving tumor control, but carries a risk of hypopituitarism of ∼ 40% at 10 years. Although dopamine agonists and somatostatin receptor ligands have been explored as medical therapy, there are currently no consistently effective medical treatments for CNFTs. There is a clear unmet need for novel safe and effective medical therapies for these comparatively common tumors. In a highly innovative approach we have used patient-derived ex vivo 3D tumoroid human CNFTs in an automated high throughput compound screen (HTS) to identify novel tumoricidal and growth inhibitory compounds for CNFTs. To date, we have screened ∼4,000 compounds and have identified 13 potential hits that inhibited tumor cell proliferation (a reduction of 76±15%) and induced apoptosis (induction rate of 8.2 ± 6.6) in the CNFT tumoroids respectively. The hit compounds to date fall into 3 categories based on their targets, namely Na+/K+-ATPase inhibitors (n=6), reactive oxygen species (ROS) regulators (n=4), and cell cycle inhibitors (n=3). Representative “hit” compounds from each group identified in our primary screen were rescreened in triplicate in 20 concentrations from 25µM to 50pM at 2-fold dilutions. Dose-response curves characterized compound doses that inhibited cell viability by 50% (IC50) and ranged from 13nM to 103nM. Two of these 3 compounds also induced 2-3-fold apoptosis at 0.1uM with the final compound displaying a potent 5-10-fold pro-apoptotic effect at 0.15uM concentration. In parallel, we used single cell RNA sequencing to validate targets that emerged from our HTS and to characterize the mechanism of action (MOA) of these hit compounds. As proof of concept, several of the known drug targets were noted to be amongst the highest differentially expressed genes in the CNFT tumor cell population. This approach validating a candidate target in conjunction with demonstrable activity of a drug for that same target in CNFTs may simultaneously provide us with a back-bone molecule to further develop with structural activity relationship analysis and/or allow us to individualize drug choice in patients based on immunocytochemical tumor target expression. Presentation: 6/1/2024

LRRK2 regulates production of reactive oxygen species in cell and animal models of Parkinson's disease.

Oxidative stress has long been implicated in Parkinson's disease (PD) pathogenesis, although the sources and regulation of reactive oxygen species (ROS) production are poorly defined. Pathogenic mutations in the gene encoding leucine-rich repeat kinase 2 (LRRK2) are associated with increased kinase activity and a greater risk of PD. The substrates and downstream consequences of elevated LRRK2 kinase activity are still being elucidated, but overexpression of mutant LRRK2 has been associated with oxidative stress, and antioxidants reportedly mitigate LRRK2 toxicity. Here, using CRISPR-Cas9 gene-edited HEK293 cells, RAW264.7 macrophages, rat primary ventral midbrain cultures, and PD patient-derived lymphoblastoid cells, we found that elevated LRRK2 kinase activity was associated with increased ROS production and lipid peroxidation and that this was blocked by inhibitors of either LRRK2 kinase or NADPH oxidase 2 (NOX2). Oxidative stress induced by the pesticide rotenone was ameliorated by LRRK2 kinase inhibition and was absent in cells devoid of LRRK2. In a rat model of PD induced by rotenone, a LRRK2 kinase inhibitor prevented the lipid peroxidation and NOX2 activation normally seen in nigral dopaminergic neurons in this model. Mechanistically, LRRK2 kinase activity was shown to regulate phosphorylation of serine-345 in the p47phox subunit of NOX2. This, in turn, led to translocation of p47phox from the cytosol to the membrane-associated gp91phox (NOX2) subunit, activation of the NOX2 enzyme complex, and production of ROS. Thus, LRRK2 kinase activity may drive cellular ROS production in PD through the regulation of NOX2 activity.

53BP1 regulates the self-renewal ability of neural stem/progenitor cells through modulating mitochondrial homeostasis

The regulation of intracellular reactive oxygen species (ROS) levels is important for maintaining the self-renewal ability of neural stem/progenitor cells (NSCs). In this study, we demonstrate that 53BP1, a DNA damage response factor known to facilitate the repair of DNA double-strand breaks, supports the maintenance of NSC stemness. ReNcell VM human NSCs with depleted 53BP1 exhibited reduced self-renewal ability compared with control NSCs, as revealed by a decrease in neurosphere size and an increase in differentiation into neural or glial cells within an NSC culture. Furthermore, 53BP1 depletion elevated cellular ROS levels, accompanied by mitochondrial abnormalities. The reduced self-renewal ability and elevated ROS levels in 53BP1-deficient NSCs were restored with the treatment of a radical scavenger, N-acetyl-l-cysteine. In addition, we investigated the functional relationship in the NSC self-renewal ability between 53BP1 and ataxia-telangiectasia mutated (ATM) or forkhead box O3a (FOXO3a), factors required for mitochondrial homeostasis, and the maintenance of NSC stemness. We found that ATM inhibition or FOXO3a deficiency, in addition to 53BP1 deficiency, did not induce further NSC stemness impairment. Collectively, our findings show that 53BP1, by cooperatively functioning with ATM and FOXO3a, supports the maintenance of NSC stemness by modulating mitochondrial homeostasis.

Regulation of Reactive Oxygen Species on Platelet Activation and Apoptosis

To investigate how reactive oxygen species (ROS) regulates the signal transduction of platelet activation and apoptosis, and to explore the relationship between platelet activation and apoptosis. Platelets were directly stimulated with thrombin or pretreated with ROS inhibitor N-acetylcysteine (NAC) before being stimulated with thrombin, and then flow cytometry was used to detect the effects of thrombin and NAC on P-selectin expression, αⅡbβ3 activation, mitochondrial membrane potential depolarization, phosphatidylserine (PS) externalization, ROS expression and platelet aggregation. Thrombin could induce the production of ROS in platelets in a concentration- and time-dependent manner. 0.01 U thrombin induced ROS-dependent high degree of integrin αⅡbβ3 activation, P-selectin expression, and platelet aggregation. The platelets induced by different concentration gradients of thrombin exhibited ROS-dependent mitochondrial membrane potential depolarization and PS externalization in platelets. After induction with thrombin for 30 min, the activation of integrin αⅡbβ3 in platelets reached its maximum level, and after 60 minutes, the depolarization of mitochondrial membrane potential in platelets reached its maximum level. However, the expression of P-selectin, depolarization of mitochondrial membrane potential, and platelet aggregation function were all inhibited to a certain extent when the platelets were pretreated with ROS inhibitor NAC and then induced with thrombin. When platelets are induced by thrombin, ROS first regulates the activation of platelets, and then regulates the apoptosis of platelets. Both platelet activation and apoptosis depend on the production of ROS in platelets, and the signals of activation and apoptosis occur orderly. Inhibiting the ROS signal in platelets can effectively inhibit the activation and apoptosis of platelets.

Harnessing Cannabis sativa Oil for Enhanced Skin Wound Healing: The Role of Reactive Oxygen Species Regulation.

Cannabis sativa emerges as a noteworthy candidate for its medicinal potential, particularly in wound healing. This review article explores the efficacy of cannabis oil in reducing reactive oxygen species (ROS) during the healing of acute and chronic wounds, comparing it to the standard treatments. ROS, produced from various internal and external sources, play a crucial role in wound development by causing cell and tissue damage. Understanding the role of ROS on skin wounds is essential, as they act both as signaling molecules and contributors to oxidative damage. Cannabis oil, recognized for its antioxidant properties, may help mitigate oxidative damage by scavenging ROS and upregulating antioxidative mechanisms, potentially enhancing wound healing. This review emphasizes ongoing research and the future potential of cannabis oil in dermatological treatments, highlighted through clinical studies and patent updates. Despite its promising benefits, optimizing cannabis oil formulations for therapeutic applications remains a challenge, underscoring the need for further research to realize its medicinal capabilities in wounds.

Revealing the vital role of sulfur site on the surface of pyrite in 1O2 formation for promoting ciprofloxacin degradation via peracetic acid activation

Pyrite has been widely utilized to activate oxidants for water treatment, yet the regulation of reactive oxygen species (ROS) by sulfur sites on its surface has been overlooked. In this study, the surface sulfur sites were regulated by thermal modification of natural pyrite in the N2 atmosphere (denoted as P-X, where X represented pyrolysis temperatures ranging from 400 to 700 °C), and these modified pyrites were employed to activate peracetic acid (PAA) for ciprofloxacin (CIP) degradation. The results revealed that the degradation rate of CIP increased as the reduced sulfur content increased, with the P600/PAA system achieving the highest apparent degradation rate (kobs = 0.0999 min−1). Quenching experiments and electron paramagnetic resonance (EPR) analysis identified various ROS involved in the P-X/PAA system, with hydroxyl radical (·OH) and singlet oxygen (1O2) identified as dominant reactive species responsible for CIP degradation. The reduced sulfur sites served as the primary active sites facilitating the conversion of organic radicals (·CH3C(O)OO) into superoxide radicals (·O2−) and 1O2. Furthermore, the P600/PAA system demonstrated robust adaptability under both acidic and neutral pH conditions, efficiently degrading CIP even in the presence of complex matrices such as Cl−, NO3−, SO42−, NH4+, or humic acid (HA) in water bodies, although HCO3− was found to inhibit CIP degradation. This study significantly enhances our understanding of the interaction between reduced sulfur sites and ROS in PAA-based advanced oxidation processes (AOPs), offering a promising technology for efficient antibiotic treatment in water purification.