Excessive Production Of Reactive Oxygen Species Research Articles

Molecular and structural analyses of voltage-dependent anion channel 2 and its anti-apoptotic function in stress and pollutant resistance in Pacific abalone

This study aimed to identify voltage-dependent anion channel 2 (Hdh-VDAC2) and determine its functional role in response to acute thermal stress, H2O2-induced stress, heavy metal toxicity, bacterial and viral infections, and during metamorphosis. Structural analysis confirmed that Hdh-VDAC2 is a pore-forming β-barrel protein. Molecular docking further confirmed the protein-protein interactions of Hdh-VDAC2 with Hdh-BAX, Hdh-caspase 3, and Hdh-BCL2. In the Hdh-VDAC2-inhibited hemocytes (HCY), apoptotic genes (Hdh-caspase-3 and Hdh-BAX) exhibited elevated mRNA expression, while the anti-apoptotic gene (Hdh-BCL2) was downregulated. Further, fluorescent techniques confirmed excessive reactive oxygen species (ROS) production, lower cell viability, elevated caspase 3 activity, and increased DNA fragmentation in Hdh-VDAC2-inhibited HCY, indicating an anti-apoptotic role of Hdh-VDAC2 in Pacific abalone. Transcriptomic analysis revealed differential expression patterns, with upregulation in the digestive gland (DG) and downregulation in the gill (GIL) and HCY when comparing heat-tolerant (HT) versus heat-sensitive (HS) abalone groups. Additionally, both cold and heat stresses induced Hdh-VDAC2 expression. Other environmental factors including H2O2, cadmium, bacteria, and viruses, were also shown to induce Hdh-VDAC2 mRNA expression in the GIL and DG of Pacific abalone. During metamorphosis, the blastula (BLS) stage exhibited higher Hdh-VDAC2 mRNA expression. These findings suggest that Hdh-VDAC2 plays a crucial anti-apoptotic role and may be a biomarker for summer mortality in Pacific abalone.

Association of NOX5 Expression with Sperm Activity and Motility in Pathospermic Infertile Men

Background: The newest NOX isoform, NOX5, has been found in mammalian spermatozoa. Many physiological and pathological situations in spermatozoa are mediated by reactive oxygen species (ROS). NOX5 is the main source of ROS in spermatozoa. Our purpose was to investigate the changes in NOX5 expression and the effect of NOX5 expression on sperm motility, chromatin integrity, and oxidative status in oligoasthenozoospermic compared to normozoospermic men. Methods: Semen samples were collected from 30 normozoospermic (NS) and 30 oligoasthenozoospermic (OAS) men. NOX5 protein expression in sperm samples was evaluated by immunohistochemistry and western blot. Oxidative stress status was evaluated by total antioxidant capacity (TAC), total oxidant capacity (TOC), and oxidative stress index (OSI) parameters. Chromatin integrity in spermatozoa was evaluated by toluidine blue staining. Results: NOX5 expression levels were significantly higher in OAS group than in NS group (p<0.001). In addition, chromatin integrity was significantly higher in the OAS group in comparison to NS group (p<0.001). TAC levels were higher in the NS group, but OSI and TOC levels were significantly higher in OAS group (p<0.001). It was found that NOX5 protein expression was positively correlated with oxidative stress and chromatin integrity and negatively correlated with motility (p<0.01). Conclusion: These results suggest that overexpression of NOX5 may be the source of excessive ROS production and oxidative stress injuries in oligoasthenozoospermic men. Considering that NOX5 expression is positively correlated with oxidative stress and chromatin integrity but negatively correlated with motility, it can be considered a biomarker to be used in assisted reproductive procedures.

Amyloid beta-activated alpha-1-syntrophin has ramifications on Rac1 activation, ROS production and neuronal cell death.

Alzheimer's disease (AD) is a progressive neurodegenerative disorder characterized by the presence of β-amyloid (Aβ)-containing extracellular neuritic plaques and phosphorylated tau-containing intracellular neurofibrillary tangles. It remains the primary neuropathological criteria for the diagnosis of AD. Additionally, several other processes are currently being recognized as significant risk factors for AD development, including the brain's susceptibility to reactive oxygen species (ROS). The ROS production is among the early signs in the progression of AD. However, the underlying mechanisms behind increased ROS production in AD remain poorly understood. We have observed SNTA1 plays critical role in regulating ROS levels in different pathological conditions. Here, we wanted to gain further insight into the role of SNTA1 in the development of AD by using IMR32 cell line. Our results show that the accumulation of Aβ plaques in Alzheimer's model neuroblastoma cells significantly increases the expression and activation of SNTA1 and MKK6 kinase. The activation of MKK6 results in the phosphorylation of SNTA1, creating a binding site for Rac1, leading to its activation and subsequent production of ROS. Excessive ROS production leads to cell cycle arrest in the G2/M phase, a hallmark of AD. Our study provides new insight into the mechanism of Aβ-mediated cell death in AD and suggests that MKK6-mediated activation of alpha-1-syntrophin promotes ROS production in neuronal cells, resulting in cell death. This study presents a mechanistic insight into Aβ-mediated cell death and could serve as a paradigm for reducing neuronal cell death in AD.

Overcoming therapeutic limitations in glioblastoma treatment: A nanocomposite inducing ferroptosis and oxeiptosis via Photodynamic therapy

Photodynamic therapy (PDT) is an effective treatment for glioblastoma (GBM) that activates photosensitizers to produce reactive oxygen species (ROS) while minimizing harm to normal tissues.However, the therapeutic outcomes of PDT are often unsatisfactory. This limitation arises partly from the challenges posed by the blood–brain barrier (BBB) in transporting photosensitizers and partly from the excessive levels of glutathione (GSH) in the tumor microenvironment (TME), which can neutralize ROS. Hypericin (HYP) has emerged as a promising photosensitizer for PDT due to its excellent photosensitizing properties and antitumor activity. Dysregulated iron metabolism is a hallmark of numerous cancers, including GBM. In this study, biodegradable tetra-sulfide-bound dendritic mesoporous organosilicas nanocomposite (NCs) modified with bovine serum albumin (BSA) were synthesized. NCs penetrates the BBB and selectively targets GBM by binding to secreted acidic protein acidic and rich in cysteine (SPARC), an albumin-binding receptor that is prominently expressed in both the BBB and GBM. Upon degradation in response to high GSH concentrations in the TME, the NCs release their payload while concurrently depleting GSH. Under laser irradiation, the ROS-generating agent HYP, loaded within the NCs, is combined with the ferroptosis inducer erastin to achieve a synergistic anti-GBM effect via PDT/ferroptosis. Additionally, the NCs induces oxeiptosis by regulating KEAP1/PGAM5/AIFM1 pathway. Consequently, NC inhibits GBM growth by inducing ferroptosis and oxeiptosis through excessive ROS production. This study demonstrates the potential of NCs to enhance the effectiveness of PDT, offering a promising therapeutic strategy for GBM patients.

Advances of Oxidative Stress Impact in Periodontitis: Biomarkers and Effective Targeting Options.

Periodontitis is the most common inflammatory oral disease that affects around 15% of adults and contributes to severe periodontal tissue destruction with subsequent tooth loosening and loss. Among the main pathogenic mechanisms underlying periodontitis, excessive reactive oxygen species production and oxidative stress play a predominant role in inducing both local and systemic damage. Current therapeutic approaches have expanded the conventional methods combined with herbal antioxidant compounds to free radical-scavenging nanomaterials and infrared laser therapy, offering promising pre-clinical evidence in periodontitis management. Herein, we review the pathogenic mechanisms of reactive oxygen species tissue damage, along with recent advances in oxidative stress biomarkers and novel targeting options.

5-Fluorouracil induces apoptosis in nutritional deprived hepatocellular carcinoma through mitochondrial damage.

5-Fluorouracil (5-FU) is the leading chemotherapeutic drug used to treat hepatocellular carcinoma, one of the major cancer diseases after atherosclerosis. Because of chemo-resistance, the success rate of treatment declines with time due to continuous drug exposure. Though autophagy induction is majorly responsible for acquired resistance, the exact role of this evolutionary conserved mechanism is unknown in cancer cell survival and suppression. The usual practice involves the combinatorial use of chemotherapeutic drugs with autophagy inhibitors like Chloroquine and Bafilomycin A, while neglecting the side effects caused by autophagy impairment in healthy cells. Starvation is a well-known physiological inducer of autophagy. In this study, by caloric modulation, we tried to circumvent the resistance imposed by prolonged drug exposure and investigated the effect of 5-FU in nutrient-sufficient and deficient conditions. Our findings show a substantial correlation between autophagy and increased cancer cell death in the presence of 5-FU, with negligible effects on normal cells. Experimental data revealed that nutritional deprivation augmented cell death in the presence of 5-FU through mitochondrial membrane damage and excessive reactive oxygen species (ROS) production, initiating apoptosis. Lipidation study also unveiled that under such combinatorial treatment cellular metabolism shifts from glucose to lipid biosynthesis. Overall, our experimental findings suggest that nutritional deprivation in combination with chemotherapeutic medication can be a new effective strategy to control hepatocellular carcinoma.

Inhibition of the FOXO1–ROCK1 axis mitigates cardiomyocyte injury under chronic hypoxia in Tetralogy of Fallot by maintaining mitochondrial quality control

IntroductionPersistent chronic myocardial hypoxia causes disturbances in mitochondrial quality control (MQC), ultimately leading to increased cardiomyocyte injury in patients with Tetralogy of Fallot (TOF). The present study aimed to identify the key effector molecules of cardiomyocyte injury under chronic hypoxia in TOF. MethodsClinical data from TOF patients were collected and whole transcriptome sequencing was performed on myocardial samples. Chronic hypoxia models were established in cardiac-specific knockout mice and cardiomyocytes, and a series of molecular experiments were used to determine the specific mechanisms involved. ResultsClinical cohort data and whole-transcriptome sequencing analysis of myocardial samples from TOF patients revealed that forkhead box O1 (FOXO1) plays an important role in chronic hypoxic cardiomyocyte injury. In a model of chronic hypoxia established in FOXO1 cardiac-specific knockout mice and FOXO1 gene-deficient cardiomyocytes, the AMPK signaling pathway regulates the expression of FOXO1, which in turn disrupts MQC by regulating the transcriptional activation of Rho-associated protein kinase 1 (ROCK1), and increasing the production of mitochondrial ROS, thereby exacerbating damage to cardiomyocytes. Excessive reactive oxygen species (ROS) production during MQC dysfunction further activates Cox7a2L to increase the assembly of the respiratory chain supercomplex. In addition, we found that miR-27b-3p partially binds to the 3′ untranslated region of FOXO1 to exert a protective effect. ConclusionsMaintenance of MQC under chronic hypoxia is achieved through a series of injury-protection mechanisms, suggesting that FOXO1 inhibition may be crucial for future mitigation of chronic hypoxic cardiomyocyte injury in TOF.

Oxidative stress causes liver injury via the damage of redox system and the apoptosis induced by mitochondria of broiler

The aim of this study was conducted to explore the effects of oxidative stress on the redox system, mitochondrial function, and apoptosis in liver of broilers. 144 one-day-old male Ross-308 broilers from the same batch had been prepared in advance and were divided into 3 treatments: normal control group (without intraperitoneal injection), normal saline group (intraperitoneal injection of normal saline), and hydrogen peroxide (H2O2) group (intraperitoneal injection of H2O2) with 6 replicates of 8 chickens each. The experimental period was 42 days. The injection volumes were 1.0 mL/kg of Ross-308 broiler body weight. On the 42nd day of the experimental period, two Ross-308 broilers were randomly selected from each cage, a total of 36 broilers were stunned by electric shock and slaughtered to collect liver samples. The results showed that compared with the non-injection group and the injection of saline group, H2O2 exposure elevated the relative weight of liver and the activities of aspartate aminotransferase (AST) and alanine aminotransferase (ALT) in serum of Ross-308 broilers (p < 0.05). Meanwhile, compared with the non-injection group and the injection of saline group, the H2O2 exposure increased the levels of reactive oxygen species (ROS), MDA, lipid peroxide (LPO) and protein carbonyl, decreased the activities of total superoxide dismutase (T-SOD), catalase (CAT), total antioxidant capacity (T-AOC) and glutathione peroxidase (GSH-Px) (p < 0.05). Compared with the non-injection group and the injection of saline group, the H2O2 exposure caused microvesicular steatosis and mitochondrial vacuolisation in the liver tissues of broilers. Additionally, after H2O2 exposure, the levels of nuclear factor erythroid 2–related factor 2 (Nrf2) positive cells were reduced and the relative percentage of hepatocyte apoptosis were increased in the liver tissues of broilers (p < 0.05). The conclusion of this study is that the oxidative stress induced by intraperitoneal injection of H2O2 could induce excessive production of ROS in broiler liver, which damage the antioxidant status and mitochondrial function of liver cells, leading to cell apoptosis. HIGHLIGHTS Oxidative stress can cause severe damage to the liver of broilers. Oxidative stress can mainly damage liver antioxidant function Oxidative stress can induce cell apoptosis by damaging mitochondria in the liver of broilers

Determination of beneficial effects of cuminaldehyde on hyperglycemiaassociated kidney malfunctions.

Type 1 diabetes mellitus is defined by the autoimmune destruction of pancreatic β cells, with diabetic nephropathy being a significant consequence. Recently, cuminaldehyde has been shown protective ability against various pathophysiology. However, its nephroprotective and anti-diabetic potential has not yet been fully understood. We, therefore, conducted the present study to evaluate the anti-hyperglycemic potential of cuminaldehyde in NRK52E cells without (control) or with high glucose medium to emulate hyperglycemic conditions. Cuminaldehyde pre-treatment at an optimal concentration of 175μM prior to high glucose addition restricted excessive reactive oxygen species (ROS) production and maintained cellular morphology to almost normal. The inhibitor study using N-acetyl-l-cysteine confirmed that blocking of ROS assists NRK52E cells in evading apoptosis. In addition, hyperglycemia was induced in 6-week-old Swiss albino mice in this investigation through the intraperitoneal injection of streptozotocin (150mgkg-1 body weight). Hyperglycemia increased the kidney-to-body weight ratio, lowered serum insulin levels, and led to significant renal tissue damage compared to control mice. Moreover, hyperglycemia disturbs cellular redox equilibrium by decreasing antioxidant enzyme functions and promoting inflammatory cytokines in kidney tissue. Administering cuminaldehyde at a dosage of 10mgkg-1 body weight for 5weeks daily after the onset of diabetes effectively ameliorated the aforementioned anomalies and reversed kidney damage by regulating inflammation-induced cell death. Overall, the research demonstrated that cuminaldehyde has hypoglycemic, antioxidant, anti-inflammatory, and anti-apoptotic properties. We believe that after conducting extensive research, this unique molecule can be used in clinical trials against diabetic nephropathy in future.

Carboxymethyl chitosan-based nanoparticles of acid response for the synergistic anti-tumor effect of PDT and chemotherapy

The combination of multiple anti-tumor methods has shown significant application potential in overcoming the limitations of monotherapy. Photodynamic therapy (PDT) and chemotherapy combination is a promising strategy for reducing drug resistance and side effects. Here, inspired by the acidic environment of tumors, carboxymethyl chitosan-based pH-responsive nanovesicles were developed to co-deliver the chemotherapeutic drug doxorubicin (DOX) and photosensitizer 5-aminolevulinic acid (5-ALA). The in vitro drug release studies revealed that drugs could be responsively released when nanoparticles were triggered by the acidic environment. The controlled-release behavior improved drug retention and reduced the administration time. Our nanoparticles could significantly enhance the killing effect of drugs on tumor cells and increase intracellular levels of reactive oxygen species (ROS) compared to monotherapy, effectively achieving the effects of combined chemotherapy and PDT. The loaded DOX could kill tumor cells and the loaded 5-ALA could enhance the content of protoporphyrin IX (PpIX), resulting in excess ROS production to improve the effects of PDT. In summary, our nanoparticles could co-deliver the drugs and exert synergistical anti-tumor of PDT and chemotherapy by suppressing tumor cell proliferation and facilitating cell apoptosis.

COMMD5 counteracts cisplatin-induced nephrotoxicity by maintaining tubular epithelial integrity and autophagy flux.

Oxidative stress mediated by reactive oxygen species (ROS) contributes to apoptosis of tubular epithelial cells (TECs) and renal inflammation during acute kidney injury (AKI). Copper metabolism MURR1 domain-containing 5 [COMMD5/hypertension-related, calcium-regulated gene (HCaRG)] shows strong cytoprotective properties. COMMD5 is highly expressed in proximal tubules (PTs), where it controls cell differentiation. We assessed its role in cisplatin-induced AKI using transgenic mice in which COMMD5 is overexpressed in the PTs. Cisplatin caused the accumulation of damaged mitochondria and cellular waste in PTs, thus increasing the apoptosis of TECs. COMMD5 overexpression effectively protected TECs from cisplatin nephrotoxicity by decreasing intracellular ROS levels, mitochondrial dysfunction, and apoptosis through the preservation of tubular epithelial integrity, thus alleviating morphological and functional kidney damage. Excessive ROS production by hydrogen peroxide led to long-term autophagy activation through an increased burden on the autophagy/lysosome degradation system in TECs, and autophagic elimination of damaged mitochondria and cellular waste was compromised. COMMD5 attenuated oxidative injury by increasing autophagy flux, possibly due to a reduction of intracellular ROS levels through maintained tubular epithelial integrity, which decreased JNK/caspase-3-dependent apoptosis. Meanwhile, COMMD5 inhibition by siRNA reduced the resistance of TECs to cisplatin cytotoxicity, as shown by disrupted tubular epithelial integrity and cell viability. These data indicated that COMMD5 protects TECs from drug-induced oxidative stress and toxicity by maintaining tubular epithelial integrity and autophagy flux and ultimately decreases mitochondrial dysfunction and apoptosis. Increasing COMMD5 content in PTs is proposed as a new protective and therapeutic strategy against AKI.NEW & NOTEWORTHY Oxidative stress overload by drug treatment causes the accumulation of damaged mitochondria that could contribute to tubulopathy. However, effective preventive treatment for drug-induced acute kidney injury remains incompletely understood. Our study showed that copper metabolism MURR1 domain-containing 5 (COMMD5) reduced mitochondrial dysfunction and increased autophagy flux by alleviating reactive oxygen species production through maintaining tubular epithelial integrity when tubular epithelial cells were under oxidative stress, thus ameliorating renal function in cisplatin-treated mice. These results uncover a novel renoprotective mechanism underlying tubular epithelial integrity and autophagy flux.

Malate dehydrogenase-2 inhibition shields renal tubular epithelial cells from anoxia-reoxygenation injury by reducing reactive oxygen species.

Ischemia-reperfusion (I-R) injury is the most common cause of acute kidney injury. In experiments involving primary human renal proximal tubular epithelial cells (RPTECs) exposed to anoxia-reoxygenation, we explored the hypothesis that mitochondrial malate dehydrogenase-2 (MDH-2) inhibition redirects malate metabolism from the mitochondria to the cytoplasm, towards the malate-pyruvate cycle and reversed malate-aspartate shuttle. Colorimetry, fluorometry, and western blotting showed that MDH2 inhibition accelerates the malate-pyruvate cycle enhancing cytoplasmic NADPH, thereby regenerating the potent antioxidant reduced glutathione. It also reversed the malate-aspartate shuttle and potentially diminished mitochondrial reactive oxygen species (ROS) production by transferring electrons, in the form of NADH, from the mitochondria to the cytoplasm. The excessive ROS production induced by anoxia-reoxygenation led to DNA damage and protein modification, triggering DNA damage and unfolded protein response, ultimately resulting in apoptosis and senescence. Additionally, ROS induced lipid peroxidation, which may contribute to the process of ferroptosis. Inhibiting MDH-2 proved effective in mitigating ROS overproduction during anoxia-reoxygenation, thereby rescuing RPTECs from death or senescence. Thus, targeting MDH-2 holds promise as a pharmaceutical strategy against I-R injury.

OsWRKY70 Plays Opposite Roles in Blast Resistance and Cold Stress Tolerance in Rice

The transcription factor WRKYs play pivotal roles in the adapting to adverse environments in plants. Prior research has demonstrated the involvement of OsWRKY70 in resistance against herbivores and its response to abiotic stress. Here, we reported the functional analysis of OsWRKY70 in immunity against fungal diseases and cold tolerance. The results revealed that OsWRKY70 was induced by various Magnaporthe oryzae strains. Knock out mutants of OsWRKY70, which were generated by the CRISPR/Cas9 system, exhibited enhanced resistance to M. oryzae. This was consistent with fortifying the reactive oxygen species (ROS) burst after inoculation in the mutants, elevated transcript levels of defense-responsive genes (OsPR1b, OsPBZ1, OsPOX8.1 and OsPOX22.3) and the observation of the sluggish growth of invasive hyphae under fluorescence microscope. RNA sequencing (RNA-seq) and quantitative real-time PCR (qRT-PCR) validations demonstrated that differentially expressed genes were related to plant-pathogen interactions, hormone transduction and MAPK cascades. Notably, OsbHLH6, a key component of the JA signaling pathway, was down-regulated in the mutants compared to wild type plants. Further investigation confirmed that OsWRKY70 bound to the promoter of OsbHLH6 by semi-in vivo chromatin immunoprecipitation (ChIP). Additionally, the loss-function of OsWRKY70 impaired cold tolerance in rice. The enhanced susceptibility in the mutants characterized by excessive ROS production, elevated ion leakage rate and increased malondialdehyde content, as well as decreased activity of catalase (CAT) and peroxidase (POD) under low temperature stress was, which might be attributed to down-regulation of cold-responsive genes (OsLti6b and OsICE1). In conclusion, our findings indicate that OsWRKY70 negatively contributes to blast resistance but positively regulates cold tolerance in rice, providing a strategy for crop breeding with tolerance to stress.

PSII-26 Effects of diquat injection on growth performance and blood and liver redox status in growing pigs

Abstract Oxidative stress, caused by excessive reactive oxygen species generation, impairs health and production performance of pigs. A number of nutrients and feed additives have antioxidative property. Our current research project is to study the antioxidative roles of methionine (a sulfur-containing amino acid) in pigs, and this abstract is to report our setup of an oxidative-stressed model by injection of diquat (dibromide monohydrate), a bipyridyl herbicide, to the pig. Barrows [n = 20, body weight (BW) = 21.5 ± 2.50 kg] were randomly allotted to two treatment groups fed a corn-and-soybean-meal-based diet that met or slightly exceeded the NRC (2012) recommended requirements of nutrients and energy. After 3 wk of feeding (Phase 1), while Group-1 pigs were intraperitoneally injected with 10 mL saline, Group-2 pigs were injected with 10 mg/kg BW diquat in 10 mL saline. After the injection, pigs were continually fed for 7 d more (Phase 2). At the end of Phases 1 and 2, average daily gain (ADG), average daily feed intake (ADFI), and gain to feed (G:F) ratios were respectively determined. Blood samples were collected on d 1, 22, and 29 of the experiment, and liver samples were collected on d 29. Commercial assay kits were used to determine the blood and liver redox status, for which the malondialdehyde (MDA) and glutathione (GSH) contents, the superoxide dismutase (SOD), catalase (CAT), and glutathione peroxidase (GPX) activities, and the total antioxidant capacity (TAC) were measured. The data was statistically analyzed using Student’s t-test. During Phase 1, there were no differences (P &amp;gt; 0.10) in initial BW, final BW, ADFI, ADG, and G:F ratio. There were no differences (P &amp;gt; 0.10) in the serum MDA contents, the serum GPX, SOD, and CAT activities, and the serum TAC and GSH contents between the two dietary treatment groups. By the end of Phase 2, however, the AFDI and ADG in Group 2 were less (P &amp;lt; 0.001) than that in Group 1. The serum MDA content in Group 2 was greater (P &amp;lt; 0.05) than in Group 1, the serum GPX activity and liver SOD activity in Group 2 was less (P &amp;lt; 0.05) than in Group 1, and the liver GPX activity in Group 2 tended to be greater (P = 0.10) than in Group 1, although there were no differences (P &amp;gt; 0.10) in serum SOD activity, serum TAC, and serum and liver CAT activities between the two treatment groups. In conclusion, the results of this study confirmed that young growing pigs intraperitoneally injected with diquat can lead to oxidative stress and serve as a model for studying antioxidant nutrients or feed additives in pigs.

Benzophenone-4 inhibition in marine diatoms: Physiological and molecular perspectives

Benzophenone-4 (BP-4), a widely utilized organic ultraviolet (UV) filter, is recognized as a pseudo-persistent contaminant in aquatic environments. To elucidate the effects and mechanisms of BP-4 on marine diatoms, an investigation was conducted on the growth rate, photosynthetic pigment content, photosynthetic parameters, antioxidant enzyme activity, malondialdehyde (MDA) levels, cellular structure, and transcriptome profile of the model species, Phaeodactylum tricornutum. The results showed a pronounced inhibition of algal growth upon exposure to BP-4, with a 144 h-EC50 value of 201 mg·L−1. In addition, BP-4 exposure resulted in a significant reduction in biomass, disruption of cell membrane integrity, and increased MDA accumulation, with levels escalating 3.57-fold at 125 mg·L−1 of BP-4. In the BP-4-treated samples, 1556 differentially expressed genes (DEGs) were identified, of which 985 were upregulated and 571 were downregulated. Gene ontology and KEGG pathway enrichment analysis revealed that the carbon fixation and carbon metabolism processes in P. tricornatum were disrupted in response to BP-4 exposure, along with excessive reactive oxygen species (ROS) production. The upregulation of genes associated with photosynthetic pigment (chlorophyll and carotenoids) synthesis, phospholipid synthesis, ribosome biogenesis, and translation-related pathways may be regarded as a component of P. tricornatum's tolerance mechanism towards BP-4. These results provide preliminary insights into the toxicity and tolerance mechanisms of BP-4 on P. tricornatum. They will contribute to a better understanding of the ecotoxicological impacts of BP-4 on the marine ecosystem and provide valuable information for elimination of BP-4 in aquatic environment by bioremediation.

Hydrogel Microsphere-Encapsulated Bimetallic Nanozyme for Promoting Diabetic Bone Regeneration via Glucose Consumption and ROS Scavenging.

The healing of bone defects among diabetic patients presents a critical challenge due to the pathological microenvironment, characterized by hyperglycemia, excessive reactive oxygen species (ROS) production, and inflammation. Herein, multifunctional composite microspheres, termed GMAP are developed, using a microfluidic technique by incorporating Au@Pt nanoparticles (NPs) and GelMA hydrogel to modulate the diabetic microenvironment for promoting bone regeneration. The GMAP enables the sustained release of Au@Pt NPs, which function as bimetallic nanozymes with dual enzyme-like activities involving glucose oxidase and catalase. The synergistic effect allows for efficient glucose consumption and ROS elimination concurrently. Thus, the GMAP effectively protects the proliferation of bone marrow mesenchymal stem cells (BMSCs) under adverse high-glucose conditions. Furthermore, it also promotes the osteogenic differentiation and paracrine capabilities of BMSCs, and subsequently inhibits inflammation and enhances angiogenesis. In vivo diabetic rats bone defect model, it is demonstrated that GMAP microspheres significantly improve bone regeneration, as verified by micro-computed tomography and histological examinations. This study provides a novel strategy for bone regeneration by modulating the diabetic microenvironment, presenting a promising approach for addressing the complex challenges associated with bone healing in diabetic patients.

Human neural stem cell-derived artificial organelles to improve oxidative phosphorylation

Oxidative phosphorylation (OXPHOS) in the mitochondrial inner membrane is a therapeutic target in many diseases. Neural stem cells (NSCs) show progress in improving mitochondrial dysfunction in the central nervous system (CNS). However, translating neural stem cell-based therapies to the clinic is challenged by uncontrollable biological variability or heterogeneity, hindering uniform clinical safety and efficacy evaluations. We propose a systematic top-down design based on membrane self-assembly to develop neural stem cell-derived oxidative phosphorylating artificial organelles (SAOs) for targeting the central nervous system as an alternative to NSCs. We construct human conditionally immortal clone neural stem cells (iNSCs) as parent cells and use a streamlined closed operation system to prepare neural stem cell-derived highly homogenous oxidative phosphorylating artificial organelles. These artificial organelles act as biomimetic organelles to mimic respiration chain function and perform oxidative phosphorylation, thus improving ATP synthesis deficiency and rectifying excessive mitochondrial reactive oxygen species production. Conclusively, we provide a framework for a generalizable manufacturing procedure that opens promising prospects for disease treatment.

Curcumin-Dichloroacetate Hybrid Molecule as an Antitumor Oral Drug against Multidrug-Resistant Advanced Bladder Cancers.

Tumor cells produce excessive reactive oxygen species (ROS) but cannot detoxify ROS if they are due to an external agent. An agent that produces toxic levels of ROS, specifically in tumor cells, could be an effective anticancer drug. CMC-2 is a molecular hybrid of the bioactive polyphenol curcumin conjugated to dichloroacetate (DCA) via a glycine bridge. The CMC-2 was tested for its cytotoxic antitumor activities and killed both naïve and multidrug-resistant (MDR) bladder cancer (BCa) cells with equal potency (<1.0 µM); CMC-2 was about 10-15 folds more potent than curcumin or DCA. Growth of human BCa xenograft in mice was reduced by >50% by oral gavage of 50 mg/kg of CMC-2 without recognizable systemic toxicity. Doses that used curcumin or DCA showed minimum antitumor effects. In vitro, the toxicity of CMC-2 in both naïve and MDR cells depended on increased intracellular ROS in tumor cells but not in normal cells at comparable doses. Increased ROS caused the permeabilization of mitochondria and induced apoptosis. Further, adding N-Acetyl cysteine (NAC), a hydroxyl radical scavenger, abolished excessive ROS production and CMC-2's cytotoxicity. The lack of systemic toxicity, equal potency against chemotherapy -naïve and resistant tumors, and oral bioavailability establish the potential of CMC-2 as a potent drug against bladder cancers.

Fucoidan from Sargassum hemiphyllum (Turner) C. Agardh inhibits human hepatoma cell (HepG2) through cell cycle arrest and apoptotic induction

Cancer has become one of the most serious diseases threatening human health, while traditional chemotherapeutic drugs have serious side effects. Drugs of marine origin have attracted many scholars due to their remarkable effectiveness, low drug resistance and low adverse reactions. In this study, the fucoidan DF1 and DF2 extracted from Sargassum hemiphyllum (Turner) C. Agardh were used to explore their effects on induced HepG2 hepatoma cell apoptosis and their relevant molecular mechanisms of apoptosis in HepG2 cells were analyzed by flow cytometry and western blotting assay. DF1 and DF2 could induce excess intracellular reactive oxygen species (ROS) production in HepG2 cells and lead to stimulation of the mitochondrial apoptotic pathway, up-regulate the protein expressions of Bax, Cytochrome C and Cleaved-Caspase-3/8, and down-regulate the protein expressions of Bcl-2 and Caspase-3/8/9. Meanwhile, DF1 and DF2 could induce HepG2 cell cycle arrest in the S-phase and up-regulate the protein expression of p21, and down-regulate the expression of Cyclin A and CDK2. This study provides a scientific basis for the development of VC/H2O2-treated fucoidans as anticancer drugs or adjuvant drugs.

Intelligent Carbon Dots with Switchable Photo-Activated Oxidase-Mimicking Activity and pH Responsive Antioxidant Activity Adaptive to the Wound Microenvironment for Selective Antibacterial Therapy.

Intelligent antibacterial agent with controllable activities adaptive to the wound microenvironment is appealing to reduce drug resistance and enhance antibacterial efficiency. In this study, celery is chosen as the carbon source to construct celery-based carbon dots (CECDs) with double activities, i.e., reactive oxygen species (ROS)-production and ROS-clearance activities. The ROS-production capability of CECDs is dependent on the oxidase (OXD)-mimicking activity, which is only photo-activated and thus artificially controlled by light to avoid the production of excess ROS. Meanwhile, the optimal OXD-mimicking activity occurrs at the pH of 5, close to microenvironmental pH at the bacterial infection site, which will enhance the antibacterial efficacy. On the other hand, CECDs exhibit the antioxidant activity at the neutral or weak alkaline pH, which will assist the healing of the wound. Thus, the conversion of ROS-production and ROS-clearance ability of CECDs can be dynamically and intelligently switched automatically with microenvironmental pH at different stages of treatment (from acid to neutral/weak basic). The proposed CECDs exert adorable selective antibacterial activity against Gram-positive bacteria and satisfactory therapeutic effect on bacteria infected mice. This study paves a new avenue to design the intelligent antibacterial nanoagent sensitive to the infected microenvironmental condition, reducing drug resistance and assisting precise medicine.