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Plants are constantly exposed to various environmental challenges, such as drought, flooding, heavy metal toxicity, and pathogen attacks. To cope with these stresses, they employ several adaptive strategies. This review highlights the potential of plant-derived smoke (PDS) solution as a natural biostimulant for improving plant health and resilience, contributing to both crop productivity and ecological restoration under abiotic and biotic stress conditions. Mitigating effects of PDS solution against various stresses were observed at morphological, physiological, and molecular levels in plants. PDS solution application involves strengthening the cell membrane by minimizing electrolyte leakage, which enhances cell membrane stability and stomatal conductance. The increased reactive-oxygen species were managed by the activation of the antioxidant system including ascorbate peroxidase, superoxide dismutase, and catalase to meet oxidative damage caused by challenging conditions imposed by flooding, drought, and heavy metal stress. PDS solution along with other by-products of fire, such as charred organic matter and ash, can enrich the soil by slightly increasing its pH and improving nutrient availability. Additionally, some studies indicated that PDS solution may influence phytohormonal pathways, particularly auxins and gibberellic acids, which can contribute to root development and enhance symbiotic interactions with soil microbes, including mycorrhizal fungi. These combined effects may support overall plant growth, though the extent of PDS contribution may vary depending on species and environmental conditions. This boost in plant growth contributes to protecting the plants against pathogens, which shows the role of PDS in enduring biotic stress. Collectively, PDS solution mitigates stress tolerance in plants via multifaceted changes, including the regulation of physico-chemical responses, enhancement of the antioxidant system, modulation of heavy metal speciation, and key adjustments of photosynthesis, respiration, cell membrane transport, and the antioxidant system at genomic/proteomic levels. This review focuses on the role of PDS solution in fortifying plants against environmental stresses. It is suggested that PDS solution, which already has been determined to be a biostimulant, has potential for the revival of plant growth and soil ecosystem under abiotic and biotic stresses. Full article

Selenium (Se) is a natural detoxifier of the heavy metal mercury (Hg), and the interaction between Se and Hg has been widely investigated. However, the ecological response of Hg to Se in Hg-contaminated farmland requires further study, especially the relationship between Se–Hg interactions and soil abiotic and biological properties. Through a field experiment, the effects of different levels of exogenous Se (0, 0.50, 0.75, 1.00, and 2.00 mg kg⁻¹) on Hg and Se transport in maize, soil properties, enzyme activities, and the microbial community in Hg-contaminated farmland were systematically studied. The Se treatments significantly reduced the Hg concentration in maize roots, stems, leaves, and grains and significantly increased the Se concentration in maize tissues. Except for the 0.75 mg kg⁻¹ Se treatment which significantly increased electrical conductivity compared to the control, other Se treatments hadnon-significant effect on soil physicochemical properties (pH, conductivity, organic matter content, and cation exchange capacity) and oxidoreductase activities (catalase, peroxidase, and ascorbate peroxide). The activities of soil invertase, urease, and alkaline phosphatase increased significantly after Se application, and the highest enzyme activities were observed with a 0.50 mg kg⁻¹ Se treatment. The bacteria and fungi with the highest relative abundance in this study were Proteobacteria (>30.5%) and Ascomycota (>73.4%). The results of a redundancy analysis and predictions of the microbial community showed that there was a significant correlation between the soil nutrient cycle enzyme activity, microbial community composition, and microbial community function. Overall, exogenous Se application was found to be a viable strategy for mitigating the impact of Hg stress on ecosystems. Furthermore, the results provide new insights into the potential for the large-scale application of Se in the remediation of Hg-contaminated farmland. Full article

Understanding the mechanisms governing forest community assembly across different growth stages is essential for revealing succession dynamics and guiding forest restoration. While much attention has been given to overstory trees, the understory regeneration layer, critical for forest succession, remains less explored, particularly regarding its stage-specific survival strategies and assembly processes. This study investigates the natural regeneration of Quercus variabilis forests in northern China, focusing on the transition from early to later growth stages. Our objectives were to (1) identify the phylogenetic and functional structures of regeneration communities at early and later stages, (2) explore their responses to environmental gradients, and (3) assess the roles of deterministic and stochastic processes in shaping community assembly. We integrated phylogenetic structure, functional traits, and environmental gradients to examine natural regeneration communities. The results revealed clear stage-dependent patterns: communities exhibited random phylogenetic and functional structures in the early growth stage, suggesting a dominant role of stochastic processes during early recruitment. In contrast, communities showed phylogenetic clustering and functional overdispersion in later growth stages, indicating the increasing influence of environmental filtering and interspecific competition as individuals developed. Generalized Dissimilarity Modeling (GDM) further revealed that dispersal limitation and pH were key predictors of phylogenetic β-diversity in the later growth stage, while total phosphorus drove functional β-diversity in the later growth stage. No significant predictors were found for β-diversity in the early stage. These findings highlight the shift from stochastic to deterministic processes during forest regeneration, emphasizing the stage-dependent nature of assembly mechanisms. Our study elucidates the stage-specific assembly rules of Q. variabilis forests and offers theoretical guidance for stage-targeted interventions in forest management to promote positive succession. Full article

Glycosylation plays a pivotal role in regulating the functions and immunogenicity of antigens. Targeting the receptor-binding domain (RBD) of the spike protein (S protein) of SARS-CoV-2, we examined the impact of different glycoforms on RBD antigen immunogenicity and the underlying mechanisms. IgG-specific antibody titers and pseudovirus neutralization were compared in mice immunized with RBD antigens bearing different glycoforms, which were prepared using glycoengineering-capable Pichia pastoris and mammalian cell expression systems with distinct glycosylation pathways. The glycosylation impacted the surface charges of the RBD antigen, and influenced its adsorption onto alum. This may further lead to variations in the antigen’s immunogenicity. The high-mannose variant of the RBD antigen (H-MAN/RBD) expressed in wild-type Pichia pastoris induced significantly higher IgG-specific antibody titers and pseudovirus neutralization activity compared with the complex RBD variant (Complex/RBD) expressed in mammalian cells (293F) or glycoengineering-capable Pichia pastoris. The rate of H-MAN/RBD adsorption onto aluminum hydroxide (alum) adjuvant was significantly higher than that of Complex/RBD. It was assumed that H-MAN/RBD might carry more negative charges because of its phosphomannose-modified surfaces, leading to a higher rate of adsorption onto the positively charged alum and enhancing the immune response. To assess the impact of phosphomannose modification on antigen immunogenicity, a yeast strain was engineered to prepare a low-mannose RBD antigen (L-MAN/RBD); additionally, a yeast strain was constructed to generate a low-phosphomannose-modified RBD antigen (L-MAN-P/RBD). In conclusion, phosphomannose modification substantially enhanced the immunogenicity of RBD by altering the surface charges of the RBD antigen and facilitating its adsorption onto alum. These findings offer novel insights and strategies for vaccine design and immunotherapeutic approaches. Full article

Three popular cultivated mushroom species (Agaricus bisporus, Lentinula edodes, and Pleurotus ostreatus) were biopreserved through a directed lactic acid fermentation process. Lactiplantibacillus plantarum strain EK11 obtained from A. bisporus fruiting bodies subjected to spontaneous lactic acid fermentation was used as a starter culture. Regardless of the mushroom species, the pH value on experimental day 7 was ≤3.75, which guarantees the shelf life of fermented products; however, it decreased to 3.51–3.6 during refrigerated storage. The number of lactic acid bacteria in the final products exceeded 7 log colony forming units per mL. The fermentation process significantly reduced the caloric value and the digestible carbohydrate content, regardless of the mushroom species. It also reduced the protein content in the P. ostreatus and L. edodes. The protein in all the analyzed samples was composed of all essential amino acids, with the dominance of glutamic and aspartic acids responsible for the umami flavor. The fermentation process significantly improved the fatty acid profile, increasing the proportion of polyunsaturated fatty acids in the P. ostreatus and L. edodes. The fermented mushrooms contained significantly lower amounts of thiamine and riboflavin than the fresh ones, except for L. edodes, where the vitamin B1 content was unchanged. The starter used did not have the ability to synthesize biogenic amines. The fermented mushrooms achieved organoleptic scores ranging from 6.83 to 8.04 on a 9-point scale. L. plantarum strain EK11 can be regarded as a suitable starter culture for lactic acid fermentation of mushrooms. Full article

This study aims to develop a gelatin methacryloyl (GelMA)-based ginsenoside Rb3 (G-Rb3) drug delivery system and investigate its application in the treatment of periodontitis and the underlying mechanisms. Periodontal ligament stem cells (PDLSCs) were obtained and identified. The appropriate concentration ranges of G-Rb3 and lipopolysaccharide (LPS) were investigated by the CCK-8 experiments. Quantitative RT-PCR, ELISA, and Western blot were performed to assess the effects of GelMA@G-Rb3 on LPS-treated PDLSCs. The possible mechanisms were determined through network pharmacology analysis and Western blot. The therapeutic effects of GelMA@G-Rb3 in rat periodontitis animal models were systematically evaluated using Micro-CT, H&E staining, Masson staining, and immunofluorescence staining. PDLSCs were successfully isolated and characterized. The in vitro results indicated that GelMA@G-Rb3 significantly alleviated LPS-induced inflammation in PDLSCs by inhibiting the p38/ERK signaling pathway and activating the PI3K/AKT signaling pathway. In vivo experiments confirmed that GelMA@G-Rb3 significantly reduced alveolar bone resorption, and promoted periodontal tissue regeneration, while simultaneously demonstrating significant regulatory effects on the MAPK signaling pathway. This study demonstrated the efficacy of the GelMA@G-Rb3 system in modulating the inflammatory responses of periodontitis and improving the periodontal tissue regeneration, which establish a solid foundation and proposed innovative therapeutic approaches for the treatment of periodontitis. Full article

Background/Objectives: Normal-weight obesity describes those with a normal body mass index (BMI) and high body fat percent. Older adults with normal-weight obesity (NWO-O) are at increased risk for cardiovascular disease (CVD), but underlying mechanisms remain unclear. This pilot study examined whether NWO-O had an unfavorable cardiometabolic response to acute high-fat meal intake compared to normal BMI, low body fat percent individuals that were both older (NWL-O) and younger (NWL-Y). Methods: Participants (N = 29) with a normal BMI were grouped as follows: NWL-Y (18–35 years, low body fat percent; n = 12), NWL-O (≥60 years, low body fat percent; n = 9), and NWO-O (≥60 years, high body fat percent; n = 8). All participants completed an abbreviated fat tolerance test (75 g fat). Fasting and 4 h blood samples were collected to measure lipids (triglycerides and high-density lipoprotein cholesterol [HDL-C]), biomarkers of intestinal permeability (lipopolysaccharide binding protein [LBP] and soluble cluster of differentiation [sCD14]), and the inflammatory marker interleukin (IL)-6. Results: NWO-O had higher percent, absolute, and trunk fat compared to NWL-Y and NWL-O (p’s ≤ 0.01). Conversely, percent lean mass was lower in NWO-O versus both NWL groups (p’s ≤ 0.01). NWO-O had higher fasting triglycerides than NWL-Y (p < 0.05), but all groups were in the clinically normal range on average (≤107 mg/dL). However, NWO-O had higher 4 h triglycerides (239.4 ± 101.0 mg/dL) compared to NWL-Y and NWL-O (p < 0.01), consistent with an adverse response. The absolute change in triglycerides was higher in NWO-O relative to NWL-Y (p < 0.01), but not compared to NWL-O (p = 0.06). Fasting IL-6 was higher in NWO-O relative to NWL-Y (p < 0.05). Fasting and 4 h sCD14 were similarly higher in NWL-O and NWO-O versus NWL-Y (p’s < 0.01). Conclusions: NWO-O had an exaggerated postprandial triglyceride response compared to younger and similar-aged NWL individuals, which could reflect hepatic very low-density lipoprotein overproduction or impaired triglyceride clearance. Future work should continue to investigate the role of postprandial dyslipidemia in NWO-O’s reported CVD risk. Full article

Diabetic wounds are characterized by a refractory healing cycle resulting from the synergistic effects of hyperglycemic microenvironment, oxidative stress, bacterial infection, and impaired angiogenesis. Conventional hydrogel dressings, with limited functionality, struggle to address the complexities of chronic diabetic ulcers. Smart hydrogels, possessing biocompatibility, porous architectures mimicking extracellular matrix, and environmental responsiveness, have emerged as promising biomaterials for diabetic wound management. This review systematically elucidates the specific response mechanisms of smart hydrogels to wound microenvironmental stimuli, including pH, matrix metalloproteinase-9 (MMP-9), reactive oxygen species (ROS), and glucose levels, enabling on-demand release of antimicrobial agents and growth factors through dynamic bond modulation or structural transformations. Subsequently, the review highlights recent advances in novel hydrogel-based sensors fabricated via optical (photonic crystal, fluorescence) and electrochemical principles for real-time monitoring of glucose levels and wound pH. Finally, critical challenges in material development and scalable manufacturing of multifunctional hydrogel components are discussed, alongside prospects for precision diagnostics and therapeutics in diabetic wound care. Full article

Bacteriocins are ribosomal synthesized antimicrobial peptides produced by bacteria, but their low yields limit industrial applications as food preservatives. This study aimed to optimize the culture conditions of Pediococcus acidilactici CCFM18 and investigate the biological properties of the bacteriocin. The culture temperature, initial pH, and culture time significantly affected the growth of P. acidilactici CCFM18 and bacteriocin production. The optimal culture conditions determined through response surface methodology (RSM) were a culture temperature of 35 °C, an initial pH of 7.0, and a growth time of 16 h. Under these conditions, bacteriocin production reached 1454.61 AU/mL, representing a 1.8-fold increase compared to pre-optimization levels. Biological characterization revealed that the bacteriocin exhibited strong thermal stability (up to 100 °C for 30 min) and pH stability (pH 2–9), but was sensitive to proteolytic enzymes, including pepsin, trypsin, papain, and protease K. The bacteriocin demonstrated antimicrobial activity against both Gram-positive and Gram-negative bacteria, including Enterococcus faecalis and Escherichia coli. These findings provide a theoretical basis for the industrial production and application of the bacteriocin. Full article

This study presents an automated industrial wastewater treatment system based on Siemens programmable logic controller (PLC) that optimizes reagent dosing, aeration, sedimentation, and sludge separation. The system uses accurate pH sensors, dosing pumps, solenoid valves, and a human–machine interface (HMI), and real-time monitoring is provided by a Teltonika TRB255 communication module (<45 sec. response time). As a result, the treatment cycle time was reduced by 31%, reagent consumption by 30%, and operator intervention was reduced from 95 to less than 15 min per day, achieving a pollutant removal efficiency of 89%. A two-layer LSTM architecture developed on the PyTorch platform predicts pH (6.7–7.7), temperature (12–20 °C), and reagent consumption (~9.8 kg/cycle). The model was trained with 240 h of data (64 neurons, learning rate 0.001). The validation loss remained stable, indicating reliable learning. The study confirms that AI-based automation provides greater process stability, meets environmental standards, and promotes sustainable resource use. The scientific novelty of this study is the application of an advanced long short-term memory (LSTM) model to predict wastewater treatment process parameters, allowing for accurate prediction of pH, temperature, flow, and reagent consumption, etc. This provides an opportunity to optimize the process and reduce costs, while ensuring high treatment efficiency and stability. Although there are several publications on the application of artificial intelligence models in the field of industrial wastewater treatment, this is a relatively new field, and there are little data in the scientific literature. Full article

Beyond its renowned gemological value, diamond serves as a vital economic mineral and a unique messenger from Earth’s deep interior, preserving invaluable geological information. Since the Mengyin region is the source of China’s greatest diamond deposits, research on the diamonds there not only adds to our understanding of their origins but also offers an essential glimpse into the development of the North China Craton’s mantle lithosphere. In this article, 50 diamond samples from Mengyin were investigated using gemological microscopy, Fourier-transform infrared (FTIR) spectroscopy, Raman spectroscopy, DiamondView™, and X-ray micro-computed tomography (CT) scanning technologies. The types of Mengyin diamonds are mainly Type IaAB, Type IaB, and Type IIa, and the impurity elements are N and H. Inclusions in diamonds serve as direct indicators of mantle-derived components, providing crucial constraints on the pressure–temperature (P–T) conditions during their crystallization. Mengyin diamonds have both eclogite-type and peridotite-type inclusions. It formed at depths ranging from 147 to 176 km, which corresponds to source pressures of approximately 4.45–5.35 GPa, as determined by the Raman shifts of olivine inclusions. The discovery of coesite provides key mineralogical evidence for subduction of an ancient oceanic plate in the source region. The surface morphology of diamonds varies when they are reabsorbed by melts from the mantle, reflecting distinctive features that record subsequent geological events. Distinctive surface features observed on Mengyin diamonds include fusion pits, tile-like etch patterns, and growth steps. Specifically, regular flat-bottomed negative trigons are mainly formed during diamond resorption in kimberlite melts with a low CO₂ (X_CO2 < ~0.5) and high H₂O content. The samples exhibit varying fluorescence under DiamondView™, displaying blue, green, and a combination of blue and green colors. This diversity indicates that the diamonds have undergone a complex process of non-uniform growth. The nitrogen content of the melt composition also varies significantly throughout the different growth stages. The N3 center is responsible for the blue fluorescence, suggesting that it originated in a long-term, hot, high-nitrogen craton, and the varied ring band structure reveals localized, episodic environmental variations. Radiation and medium-temperature annealing produce H3 centers, which depict stagnation throughout the ascent of kimberlite magma and are responsible for the green fluorescence. Full article

This study aims to investigate the regulatory effect of exogenous melatonin (MT) on the growth and development of cucumbers subjected to salt stress. Using the XinTaiMiCi material and indoor pot culture method, seven treatments were set up: control group (CK), T0 (salt treatment group, 150 mM S + 0 μM MT), T1 (150 mM S + 25 μM MT), T2 (150 mM S + 50 μM MT), T3 (150 mM S + 100 μM MT), T4 (150 mM S + 150 μM MT), and T5 (150 mM S + 200 μM MT). Changes in plant height, stem diameter, leaf area, relative chlorophyll content, antioxidant enzyme activity, reactive oxygen species content, and osmotic adjustment substance content in cucumber seeds and seedlings under different treatments were studied, and a correlation analysis of these indicators was conducted. Meanwhile, the expression of salt stress-related genes was detected in all seven treatment groups. The results showed that, compared to the CK, T0 significantly reduced the hypocotyl length, root length, hypocotyl diameter, root diameter, and fresh and dry weights of cucumber seeds; in the later stage of salt stress treatment, T0 significantly increased the activities of superoxide dismutase (SOD), peroxidase (POD), catalase (CAT), and malondialdehyde (MDA) and the content of soluble protein in seeds. Additionally, T0 significantly increased the plant height, root length, stem diameter, leaf area, and fresh and dry weights of cucumber seedlings per plant; in the later stage of salt stress treatment, T0 significantly increased the activities of SOD, POD, CAT, and MDA and the content of soluble protein and chlorophyll in leaves. Compared to T0, the application of 50 μmol·L⁻¹ MT under salt stress significantly increased the plant height, stem diameter, root length, leaf area, and fresh and dry weights of cucumber seedlings per plant; significantly increased the activities of SOD, POD, and CAT; decreased the MDA activity; and significantly increased the content of soluble protein and chlorophyll. Under salt stress conditions, the exogenous application of low-concentration melatonin increased the expression levels of salt stress response genes (such as CsSOS, CsNHX, CsHSF, and CsDREB) in cucumber. The germination rate (GR), germination potential (GP), germination index (GI), plant height (PH), root length (RL), leaf area index (LAI), fresh weight (FW), dry weight (DW), soluble protein (SP), relative chlorophyll content (SPAD), POD, CAT, and SOD of cucumber seedlings exhibited significant positive correlations, whereas they were negatively correlated with MDA content. In conclusion, the application of 50 μM MT can effectively alleviate the oxidative and osmotic stress caused by a high-salt environment in cucumber, promote cucumber growth, and improve salt tolerance. Full article

To develop membranes capable of efficient and switchable emulsion separation under variable pH conditions, pH-responsive surfaces were engineered on poly(ethylene terephthalate) track-etched membranes (PET TeMs) via a two-step UV-initiated RAFT graft polymerization process. Initially, polystyrene (PS) was grafted to render the surface hydrophobic, followed by the grafting of poly(methacrylic acid) (PMAA) to introduce pH-responsive carboxyl groups. Optimized conditions (117 mM MAA, RAFT:initiator 1:10, 60 min UV exposure at 10 cm) resulted in PET TeMs-g-PS-g-PMAA surfaces exhibiting tunable wettability, with contact angles shifting from 90° at pH 2 to 65° at pH 9. Successful grafting was confirmed by FTIR, AFM, SEM, TGA, and TB dye sorption. The membranes showed high degree of rejection (up to 98%) for both direct and reverse emulsions. In direct emulsions, stable flux values (70 ± 2.8 to 60 ± 2.9 L m⁻² h⁻¹ for cetane-in-water and 195 ± 8.2 to 120 ± 6.9 L m⁻² h⁻¹ for o-xylene-in-water) were maintained over five cycles at 900 mbar, indicating excellent antifouling performance. Reverse emulsions initially exhibited higher flux, but stronger fouling; however, flux recovery reached 91% after cleaning. These findings demonstrate the potential of PET TeMs-g-PS-g-PMAA as switchable, pH-responsive membranes for robust emulsion separation. Full article

Background: Abrupt dietary changes may disrupt gut microbiota populations and lead to gastrointestinal issues. This study aimed to determine the effects of live Bacillus pumilus SG154 or Lacticaseibacillus paracasei 327 postbiotic on fecal characteristics and microbiota populations of dogs following an abrupt diet change. Methods: Twelve healthy adult English pointer dogs (6.38 ± 2.75 yr) were used in a replicated 3 × 3 Latin square design to test the following treatments: (1) placebo (control; 250 mg maltodextrin/d); (2) live B. pumilus [5 × 10⁹ colony-forming units (CFU)/d]; and (3) L. paracasei postbiotic (100 mg; derived from 2 × 10⁹ CFU/d). Each period lasted 42 days, with the diet change occurring on day 28. Fecal samples were scored and analyzed for pH, dry matter content, and microbiota before and 2, 6, 10, and 14 days after the diet change. Results: The abrupt diet change increased (p < 0.01) fecal pH, increased (p < 0.01) the dysbiosis index, decreased (p < 0.0001) fecal dry matter, and led to a large shift in the fecal microbiota community. Fecal scores were lower (p < 0.05) in the B. pumilus group. B. pumilus reduced (p < 0.05) the relative abundance of fecal Prevotella and Muribaculaceae, while both treatments (B. pumilus; L. paracasei) increased (p < 0.05) the relative abundance of fecal Holdemanella. Conclusions: These results suggest that an abrupt diet change leads to large shifts in fecal microbiota and modified fecal characteristics. The supplementation with a B. pumilus probiotic and a L. paracasei postbiotic slightly altered the relative abundance of a few microbial taxa but was unable to attenuate most responses. Full article

The present study was conducted to evaluate the individual and combined effects of dietary crude protein levels and magnetic water treatment on the growth performance, water quality, body composition, physiological responses, and immunity of Oreochromis niloticus. Using a 3 × 2 factorial design, three levels of dietary crude protein (25%, 30%, and 35%) and two water types (magnetized and non-magnetized) were tested. A total of 180 juvenile tilapia (average initial weight: 4.13 ± 0.004 g) were randomly assigned to six treatment groups and reared for 10 weeks. Results showed that magnetic water treatment significantly improved dissolved oxygen and pH, while reducing ammonia, nitrite, and nitrate concentrations. Growth performance indicators, including final weight, specific growth rate, feed conversion ratio, and average daily gain, were significantly improved by both magnetic water and increased dietary protein. Carcass crude protein content improved with both the higher dietary protein level and magnetic water, while lipid content decreased. Liver and kidney function indicators (AST, ALT, ALP, and urea) were significantly improved by magnetic treatment and higher protein levels. Blood biochemical markers (TP, ALB, and GLO) were elevated, while glucose, cholesterol, and triglycerides were reduced by magnetic water; significant interactions were observed for globulin, triglycerides, and total protein. Antioxidant enzyme activities (SOD, CAT, and GPx) increased, and MDA decreased in response to magnetic water and high-protein diets. Similarly, digestive enzyme activities (lipase, protease, and amylase) and immune parameters (IgM and lysozyme) were significantly improved, with the best values recorded in the 35% protein + magnetic water group. In conclusion, magnetic water treatment and dietary protein level independently and interactively affect the physiological performance and health of Nile tilapia, with the best outcomes obtained at 35% protein under magnetic water conditions. Full article