Search Results (1,026)

This study investigated the antibacterial activities of Se-Al/Zn layered double hydroxide (LDH) and its polycarbazole (PCz) hybrid against Gram-positive Bacillus subtilis and Gram-negative E. coli cells. Antibacterial performances were evaluated using zone of inhibition assays, viable cell counting, and measurement of metabolic activity based on intracellular ATP levels. The collective results showed that both materials exhibited significant antibacterial activity, with PCz–Se–Al/Zn LDH demonstrating enhanced antibacterial activity compared to Se–Al/Zn LDH. Fluorescent live/dead staining and scanning electron microscopy revealed that treatment with either material resulted in loss of metabolic activity and induction of a non-culturable state in bacterial cells, without observable membrane damage or pronounced morphological changes. Possible antibacterial mechanisms of action associated with LDH and PCz–LDH systems are briefly discussed. Full article

Phytophthora blight, caused by Phytophthora capsici, an oomycete pathogen belonging to the phylum Oomycota, is a major soil-borne disease that limits the cultivation of pepper (Capsicum annuum). In this study, the bacterium Serratia plymuthica MM was evaluated for both its antagonistic ability and plant growth-promoting (PGP) potential. The sterile fermentation filtrate of S. plymuthica MM exhibited strong antifungal activity in vitro, inhibiting the mycelial growth of P. capsici by up to 88.32%. In pot experiments, Serratia plymuthica MM significantly reduced both disease incidence and disease severity of Phytophthora blight in pepper plants, achieving control efficacies of 88.33% (preventive application) and 55.56% (therapeutic application). Microscopic observations revealed severe hyphal abnormalities, including distortion, shrinkage, collapse, and fragmentation. Furthermore, propidium iodide (PI) and DAPI double staining provided cellular-level evidence of antifungal activity, demonstrating concentration-dependent disruption of membrane integrity and nuclear organization in P. capsici hyphae, which was supported by pronounced increases in ion leakage from pathogen cells. Further, S. plymuthica MM exhibited PGP traits, including nitrogen fixation, phosphate solubilization, siderophore production, and indole-3-acetic acid (IAA) synthesis. Pot experiments using the pepper cultivar ‘Longjiao’ (Capsicum annuum L. cv. Longjiao) confirmed significant growth promotion and enhanced activities of key defense-related enzymes (POD, PPO, PAL, and CAT). Stable colonization of pepper roots was verified by green fluorescent protein (GFP) labeling, demonstrating the strain’s persistence in the rhizosphere. Collectively, these results highlight the dual role of S. plymuthica MM in suppressing P. capsici and promoting pepper growth, supporting its potential as an eco-friendly biocontrol agent for sustainable pepper production. Full article

Chloroplast development plays a crucial role in plant de-etiolation, a process in which plants switch from growth in darkness to light-driven development, known as photomorphogenesis. This study provides evidence that CIA2 (Chloroplast Import Apparatus 2) and CIL (CIA2-Like) contribute to chloroplast biogenesis, likely by affecting and regulating PSII activity and related gene expression. Although their precise molecular roles remain unclear, our findings support their possible involvement in chloroplast development. This is indicated by downregulation of foliar chlorophyll content, chlorophyll a fluorescence parameters, chloroplast size, and gene expression of PSII molecular markers in the cia2cil double mutant during de-etiolation. Chlorophyll a fluorescence and quantitative gene expression analysis during de-etiolation revealed a significant reduction in PSII maximal efficiency and non-photochemical quenching, as well as deregulated expression of genes such as LHCB2.1 and psbA. According to the immunoblotting and microscopy imaging results, there is an impaired function of PSII and a compromised ultrastructure of the chloroplast membranes in cia2cil plants. However, in CIA2p::CIA2_cia2cil and 35Sp::CIA2_cia2cil complementation lines, reversion of this phenotype was observed. These results suggest a supporting role for CIA2 and CIL in the plant de-etiolation process, expanding our understanding of chloroplast biogenesis regulation. Full article

Ferroptosis is a novel regulated cell death caused by the accumulation of iron-dependent ROS and excessive local lipid peroxides in the membrane, widely involved in various physiological and pathological processes. Ferroptosis has emerged as a key mechanism in radiotherapy response. Radiotherapy is an effective treatment for many types of cancers, which not only causes double-stranded DNA break-induced apoptosis, but also induces the production of ROS, leading to oxidative stress and tumor cell death. Recent studies have shown that ionizing radiation in radiotherapy can induce ferroptosis in tumor cells. The combination of radiotherapy and ferroptosis induction can synergistically induce ferroptosis to enhance the sensitivity of tumor cells to radiotherapy, making ferroptosis induction a promising radiosensitization strategy. In this review, we summarize the characteristics and regulation of ferroptosis, analyze the mechanism of radiotherapy-induced ferroptosis, and specifically discuss the different strategies of inducing ferroptosis for radiosensitization. We also point out the shortcomings, future prospects, and research directions of this strategy. Full article

Thyme oil (TO) is emerging as a promising candidate to counteract antimicrobial resistance due to its renowned antimicrobial and anti-inflammatory properties. However, rapid gastric absorption of its bioactive compounds limits its intestinal delivery, where its action is required, so the protection of these components is necessary. This pilot study optimized TO-loaded emulsions for targeted intestinal release. High-shear homogenization and membrane emulsification were compared to formulate single oil in water (O/W) and double water in oil in water (W/O/W) emulsions, screening emulsifiers (lecithin, Tween 20, Tween 80) and functional biopolymers (pectin, sodium alginate). High-shear homogenization with lecithin (0.5%), pectin (1.80%), and sodium alginate (0.2%) yielded stable submicron O/W emulsion (Span = 0.5; d(v,0.5) = 0.21 µm), achieving electrostatic stabilization (ζ-potential = −51.5 ± 1.5 mV) at a target poultry dosage. A pH-responsive behavior was observed: protective hydrogel formed in gastric conditions (d(v,0.5) = 2.64 µm) and maintained stability at intestinal pH (d(v,0.5) = 3.03 µm). Membrane emulsification enabled precise droplet control under mild conditions, producing monodisperse O/W emulsions (d(v,0.5) = 38–59 µm; Span ≤ 1.0) and W/O/W double emulsions (d(v,0.5) = 26.5 µm; Span = 0.6) with ultra-low interfacial tension (0.52 mN·m⁻¹). Repeated membrane passes reduced droplet size to ~6.6 µm. These systems represent a foundational step toward bioactive intestinal delivery, providing a viable antibiotic-free strategy for sustainable livestock production. Full article

Background: Structured lipids, composed of re-esterified triacylglycerols containing eicosapentaenoic acid (EPA), docosahexaenoic acid (DHA), and medium-chain fatty acids, may influence metabolism and endurance performance. This trial aimed to evaluate the effects of eight weeks of structured lipid supplementation on substrate utilization, erythrocyte fatty acid content, and endurance performance in healthy untrained men. Methods: In a double-blind, placebo-controlled, randomized design, 36 participants (18 per group) received either structured lipids or placebo supplementation for eight weeks. Pre- and post-supplementation assessments included maximal oxygen uptake, time to exhaustion, substrate oxidation during exercise at 65% VO_2max, and erythrocyte membrane fatty acid content. Non-parametric statistical methods were used to analyze within- and between-group differences. Results: After supplementation, the structured lipids group showed statistically significant within-group changes in substrate utilization, including lower respiratory exchange ratio and higher percentage fat oxidation, total fat oxidation, and mean fat oxidation rate. Statistically significant increases were also observed in erythrocyte EPA + DHA content and time to exhaustion. Compared with the placebo group, the structured lipids group showed statistically significant post-intervention differences in substrate oxidation, erythrocyte EPA + DHA levels, and time to exhaustion. Conclusions: Eight weeks of structured lipid supplementation increased erythrocyte membrane EPA and DHA and enhanced fat oxidation during moderate-intensity exercise in untrained men. Although endurance performance improved, the change was within natural variability and showed substantial interindividual differences. Further rigorously controlled studies are needed to determine whether these metabolic adaptations yield meaningful functional benefits. Full article

Clean water remains a pressing global challenge and developing membranes that are both efficient and durable is critical. This study combined two polymers, polyethersulfone (PES) and sulfone-modified polysulfone (SPSf), with NiFe-layered double hydroxides (LDHs) to create a new class of multifunctional membranes. The membranes were characterized using FTIR, SEM, water contact angle, and zeta potential. The addition of NiFe-LDH fillers improved the hydrophilicity and surface structure of the membranes and enhanced the separation performance of the resulting membranes. The best-performing membrane (M3, with 2 wt.% NiFe-LDH) delivered pure water flux of about 218 L.m⁻²h⁻¹, which was nearly three times higher than that of the pristine PES/SPSf membrane. Furthermore, M3 removed approximately 92.4% of bovine serum albumin (BSA), attributed to the synergistic combination of size exclusion, electrostatic repulsion, and hydrophilicity. The membrane also showed excellent antifouling properties, maintaining over 65.9% and 71.2% flux recovery after three fouling–cleaning cycles for BSA solution and surface water, respectively. Importantly, the M3 membrane achieved high removal efficiencies for heavy metals, rejecting 91% of Cd²⁺, 93% of Pb²⁺, and 88% of Cu²⁺. These results highlight how the synergy between PES/SPSf and NiFe-LDH can overcome the common challenges of fouling and low metal ion rejection, offering a promising route toward practical and sustainable water treatment solutions. Full article

Drought severely limits plant productivity, and understanding its regulatory mechanisms remains essential. Here, we characterize Lipid Transport Superfamily-Polyketide cyclase/dehydrase (LTS-PYL), a PYR/PYL/RCAR-domain gene, using Arabidopsis overexpression and CRISPR-Cas9 genome-edited lines to elucidate its role in drought adaptation. LTS-PYL overexpression enhanced early seedling growth, increasing root length (RL) by 40% and 31%, whereas genome-edited lines exhibited severe defects, including 42%, 28% reductions in fresh weight and 63%, 50% decreases in root length relative to WT-T. Under drought stress, overexpression lines displayed strong growth and reproductive resilience, with shoot length (SL) increased by up to 80%, silique length (Sil L) by 61%, and seed number doubled compared with WT-T. In contrast, genome-edited lines showed marked reductions in these traits, confirming their drought sensitivity. LTS-PYL overexpression strongly suppressed oxidative stress, reducing H₂O₂ by 74% and 68% and O₂⁻· by 39% and 38%, while increasing relative water content (RWC) by 42% and 39%. Genome-edited lines exhibited elevated (H₂O₂, O₂⁻·) and up to 33% lower RWC. Antioxidant capacity was also strengthened in overexpression plants, with catalase (CAT) and peroxidase (POD) activities increasing by 138%, 168% and 62%, 148%, and malondialdehyde (MDA) and electrolyte leakage (EL) reduced by 23%, 37%, relative to WT-T. Conversely, genome-edited lines showed weakened antioxidant defenses and higher membrane damage. Transcriptionally, overexpression activated drought-responsive genes, elevating LTS-PYL (604%, 472%), DREB2A (227%, 200%), and ABA levels (48%, 34%), whereas genome-edited lines showed strongly reduced expression and ABA decreases of 66%, 62%. Additionally, LTS-PYL enhanced osmotic adjustment, increasing proline (58%, 53%), sugars (37%, 46%), and sucrose (111%, 100%), while limiting chlorophyll (Chl) loss to 9%, 20%. Genome-edited lines exhibited reduced osmolytes and severe chlorophyll decline. Overall, LTS-PYL acts as a strong positive regulator of drought tolerance, integrating ABA signaling, osmotic adjustment, ROS detoxification, and transcriptional activation. Full article

The combination of supported lipid bilayers (SLBs) with the Quartz Crystal Microbalance with Dissipation monitoring (QCM-D) has been proven to be a powerful tool to simultaneously monitor mass and viscoelastic changes related to membrane binding-events. In this work, the above methodology is employed for the study of the interaction of the Early Endosomal Antigen 1 (EEA1) to a model lipid bilayer that mimics the early endosome (EE) membrane, focusing on the membrane composition. Starting with the formation of a lipid bilayer through the vesicles fusion technique, we investigated the formation of SLBs that incorporate phosphatidylinositol 3-phosphate (PI(3)P), a key component for EEA1 binding, in combination with other lipids, e.g., (1,2-dioleoyl-sn-glycero-3)-phosphocholine (DOPC), -phosphoserine (DOPS), -phosphoethanolamine (DOPE), and cholesterol (Chol). The interaction of the full-length coiled-coil EEA1 to the formed SLBs was further studied in real time with the QCM-D and characterized with respect to the lipid composition and pH. Our findings confirm that PI(3)P is essential for the EEA1–membrane interaction, while it was shown that Chol and phosphatidylserine greatly influence the binding event. In fact, including 30% Chol in a PI(3)P (3%):PS (6%) SLB resulted in almost double EEA1 binding than in the absence of Chol. Moreover, we employed the QCM-viscoelastic model available to analyze the QCM-D data with emphasis on the study of the protein conformation. Our results showed that, in our in vitro system, EEA1 is not fully extended and/or highly packed, but is mainly in a bent, distorted conformation with an average size close to 100 nm. This study complements previous works employing in vitro assays, also demonstrating the ability to reconstitute more complex biomimetic EE membranes containing inositol phospholipids on a QCM surface for the study of EEA1 binding. Full article

In this study, three distinct hydrolysates, which are designated Dur-I, Dur-II, and Dur-III, were generated from extrusion-pretreated Durvillaea antarctica biomass by applying viscozyme, cellulase, and α-amylase, respectively. Chemical analyses demonstrated distinct compositional differences among the extracts, whereas FTIR spectra verified the presence of fucose-containing sulfated polysaccharides. Furthermore, NMR analyses revealed pronounced structural variations among the extracts. To investigate neuroprotective properties of Dur-I, Dur-II, and Dur-III, rotenone (Rot) was added to SH-SY5Y cells that had been pretreated with Dur-I/II/III. Here, flow cytometry was employed to assess changes in mitochondrial membrane potential (MMP), Bcl-2 expression, cytochrome c release, caspase-9, -8, and -3 activation, as well as DNA fragmentation. The protective effect of Dur-I/II/III pretreatment of SH-SY5Y cells on the Rot-induced death process was further investigated using cell cycle and annexin V-fluorescein isothiocyanate (FITC)/PI (propidium iodide) double staining analyses. The results reveal that the Rot-induced apoptotic factors were all recovered by the pretreatment of Dur-I/II/III. Moreover, cell cycle and annexin V-FITC/PI double staining analyses also indicated that Dur-I/II/III were capable of protecting SH-SY5Y cells from Rot-induced cytotoxicity. Therefore, these Dur extracts are considered as good candidates for the prevention and treatment of neurodegeneration induced by oxidative stress. Full article

Short-term hypothermic storage at 4 °C represents a promising non-freezing alternative for transporting bovine embryos and synchronizing assisted reproductive procedures. However, chilling induces oxidative stress, mitochondrial dysfunction, and apoptosis, which markedly impair post-preservation embryonic viability. Glutathione (GSH), a key intracellular antioxidant, may mitigate these damaging effects, yet its protective mechanisms during bovine blastocyst hypothermic preservation remain unclear. Here, we investigated the impact of exogenous GSH supplementation on the survival, hatching ability, cellular integrity, mitochondrial function, and developmental potential of bovine blastocysts preserved at 4 °C for seven days. Optimization experiments revealed that 4 mM GSH provided the highest post-chilling survival and hatching rates. Using DCFH-DA, TUNEL, and γ-H2AX staining, we demonstrated that 4 °C preservation significantly increased intracellular reactive oxygen species (ROS), DNA fragmentation, and apoptosis. GSH supplementation markedly alleviated oxidative injury, reduced apoptotic cell ratio, and decreased DNA double-strand breaks. MitoTracker and JC-1 staining indicated severe chilling-induced mitochondrial suppression, including decreased mitochondrial activity and membrane potential (ΔΨm), which were largely restored by GSH. Gene expression analyses further revealed that chilling downregulated antioxidant genes (SOD2, GPX1, TFAM, NRF2), pluripotency markers (POU5F1, NANOG), and IFNT, while upregulating apoptotic genes (BAX, CASP3). GSH effectively reversed these alterations and normalized the BAX/BCL2 ratio. Moreover, SOX2/CDX2 immunostaining, total cell number, and ICM/TE ratio confirmed improved embryonic structural integrity and developmental competence. Collectively, our findings demonstrate that exogenous GSH protects bovine blastocysts from chilling injury by suppressing ROS accumulation, stabilizing mitochondrial function, reducing apoptosis, and restoring developmental potential. This study provides a mechanistic foundation for improving 4 °C embryo storage strategies in bovine reproductive biotechnology. Full article

The concentration of extracellular vesicles (EVs) in the peripheral blood of COVID-19 patients is increased. Nevertheless, their potential role in the transmission of infection remains unclear. This study was performed to determine whether EVs produced by the sub-genomic replicon system developed in Baby Hamster Kidney (BHK-21) cells could transfer SARS-CoV-2 replicon RNA, leading to the establishment of a viral replication system in human cells. Purified EVs from the SARS-CoV-2 sub-genomic replicon cell line BHK-21 were cultured with a naive human cell line. The success of EV-mediated transfer of SARS-CoV-2 replicon RNA and its productive replication was assessed using G-418 selection, a luciferase assay, immunostaining, and Western blot. We found that the A549 cell line cultured with EVs isolated from SARS-CoV-2 BHK-21 replicon cells developed G-418-resistant cell colonies. SARS-COV-2 RNA replication in A549 cells was confirmed by nano luciferase, Nsp1 protein. SARS-CoV-2 RNA replication causes massive morphological changes. Treatment of cells with the FDA-approved Paxlovid demonstrated a dose-dependent inhibition of viral replication. We isolated two human epithelial cell lines (gastrointestinal and neuroblastoma) and one vascular endothelial cell line that stably support high-level replication of SARS-CoV-2 sub-genomic RNA. Viral elimination did not revert the abnormal cellular shape, vesicle accumulation, syncytia formation, or EV release. Our study’s findings highlight the potential implications of EV-mediated transfer of replicon RNA to permissive cells. The replicon model is a valuable tool for studying virus-induced reversible and irreversible cellular reprogramming, as well as for testing novel therapeutic strategies for SARS-CoV-2. Full article

Photocatalytic reduction of CO₂ into value-added chemicals offers a sustainable route to mitigate greenhouse gas emissions while producing renewable fuels. However, conventional TiO₂-based systems suffer from limited visible-light activity and inefficient reactor configurations. Here, we developed electrospun polyacrylonitrile (PAN) membranes embedded with TiO₂-Cu₂O heterojunction nanoparticles and integrated them into a custom crossflow photocatalytic membrane reactor. The reactor employed bifacial illumination using a solar simulator (front) and a xenon/mercury lamp (back), each calibrated to 1 Sun (100 mW·cm⁻²). Membrane morphology was characterized by SEM, and chemical composition was confirmed by XPS. Photocatalytic performance was evaluated in CO₂-saturated 0.5 M potassium bicarbonate solution under continuous flow. The PAN/ TiO₂-Cu₂O membrane exhibited a methanol production rate of approximately 300 μmol·g⁻¹·h⁻¹ under dual-light illumination, outperforming single illumination, PAN-TiO₂, and PAN controls. Enhanced activity is attributed to extended visible-light absorption, improved charge separation at the TiO₂-Cu₂O heterojunction, and optimized photon flux through bifacial illumination. The electrospun architecture provided high surface area and porosity, facilitating CO₂ adsorption and catalyst dispersion. Combining heterojunction engineering with bifacial reactor design significantly improves solar-driven CO₂ conversion. This approach offers a scalable pathway for integrating photocatalysis and membrane technology into sustainable fuel synthesis. Full article

Background/Objectives: Limited residual bone height in the atrophic posterior maxilla complicates implant placement. Transcrestal sinus elevation can be used to correct bone shrinkage after sinus pneumatization or crestal bone loss. This study evaluated a minimally invasive, one-stage transcrestal sinus lift using a double-layer crosslinked collagen scaffold (MCCS) with autogenous bone from the implant osteotomy site in patients with RBH ≤ 6 mm. Methods: In this prospective series, 11 patients (48–64 years, mean RBH 4.75 mm, SD 0.95 mm) underwent one-stage transcrestal sinus floor elevation with simultaneous implants. After osteotomy, autogenous bone chips collected during drilling were compacted into the site, and two layers of MCCS were placed under the elevated Schneiderian membrane. Buccal and palatal bone heights were measured on CBCT before and after surgery to assess vertical bone gain (ΔRBH). Results: All implants achieved stable osseointegration. Mean ΔRBH was approximately 3.1 ± 0.9 mm (combined buccal–palatal). No postoperative complications occurred. Two small Schneiderian membrane perforations were sealed intraoperatively by MCCS placement, with uneventful healing. Follow-up imaging showed maintenance of the augmented bone around the implants. Conclusions: This double-layer MCCS plus autogenous bone approach is a safe, effective, and minimally invasive transcrestal sinus lift for atrophic maxillae. It yielded crestal bone gains even with minimal initial RBH, leveraging the palatal sinus wall’s osteogenic potential and the implant’s tent-pole effect. The MCCS scaffold maintained space for bone formation and enabled immediate sealing of any membrane perforations. This one-stage protocol is viable for implant placement in low-RBH sites. Full article

In Proton Exchange Membrane Water Electrolysis (PEMWE), the two-phase flow distribution in the anode field significantly affects overall electrolysis performance. Based on visualized experimental data, in this paper, the reaction kinetics equations were theoretically revised, and a three-dimensional, two-phase, non-isothermal, multi-physics coupled model of the electrolysis was developed and experimentally validated. Four different configurations of rectangular turbulence promoters were designed within the anode serpentine flow field and compared with a conventional serpentine flow field (SFF) in terms of their multi-physics distribution characteristics. The results showed that, in the double-row rectangular block serpentine flow field (DRB SFF), the uniformity of liquid water saturation, temperature, and current density improved by 16.6%, 0.49% and 40.8%, respectively. The normal mass transfer coefficient increased by a factor of 6.3, and polarization performance improved by 6.98%. A cross-arranged turbulence promoter structure was further proposed. This design maintains effective turbulence while reducing flow resistance and pressure drop, thereby enhancing mass transfer efficiency and overall electrolysis performance through improved bubble fragmentation. Full article