Search Results (28,066)

Acne vulgaris is a prevalent inflammatory disease of the pilosebaceous unit in which Cutibacterium acnes (C. acnes) contributes to lesion initiation and persistence, supporting antibacterial interventions as a component of clinical management. Given the essential role of the 50S large ribosomal subunit—particularly 23S rRNA sites in the peptidyl transferase center and nascent peptide exit tunnel—in C. acnes protein synthesis and viability, targeting the 50S offers an effective path to lead discovery for acne treatment. Here, we present an integrated computational–experimental workflow to identify anti-C. acnes candidates from a 186,659-compound natural product library. Curated 50S/23S ligands trained and validated two ML-QSAR regression models built on different molecular fingerprints (MACCS keys and PubChem 2D) to predict anti-C. acnes activity and rapidly triage the library. Compounds were further screened by ADMET filtering and structure-based docking to 23S rRNA pockets, followed by cluster and interaction analysis. Among six experimental hits, three compounds exhibited MICs against C. acnes of ≤8 μg/mL, with tripterin, a pentacyclic triterpenoid, being the most potent (0.5–2 μg/mL across two acne-relevant strains). Collectively, these results indicate that a 50S ribosomal-focused, multistage computational screening workflow, integrated with in vitro assays, efficiently prioritizes compounds with quantifiable anti-C. acnes activity across a broad range of natural products. Full article

Various surfactants have been applied for the remediation of polycyclic aromatic hydrocarbon (PAH)-contaminated environments, but their roles in bioremediation remain controversial. This study focused on rhamnolipid (a typical surfactant) and Burkholderia sp. FM-2 (a high-efficiency phenanthrene-degrading bacterium), investigating its effects on phenanthrene solubilization and biodegradation by analyzing cell surface characteristics and gene expression differences. Results showed that low concentrations of rhamnolipid (20–120 mg/L) promoted phenanthrene degradation, while high concentration (400 mg/L) exerted an inhibitory effect. At 20–56 mg/L, rhamnolipid altered the bacterial surface morphology and functional groups, facilitated lipopolysaccharide release, enhanced cell surface hydrophobicity, and increased zeta potential. When the rhamnolipid concentration was 20 mg/L, the phenanthrene degradation rates of cytoplasmic enzymes, periplasmic enzymes, and extracellular enzymes produced by the bacterium reached over 98% after 15 days of enzyme system culture, demonstrating its role in promoting enzyme production and activity. Transcriptomic analysis revealed that 56 mg/L (1 CMC) rhamnolipid enhanced degradation through multi-pathway regulation of gene expression: upregulating the gene encoding protocatechuate 3,4-dioxygenase to strengthen benzene ring cleavage; increasing the expression of genes related to ABC transporters and protein transport to promote phenanthrene transmembrane transport; and activating genes involved in metabolic processes such as pyruvate metabolism and the tricarboxylic acid (TCA) cycle to enhance central carbon metabolic flux. This regulatory mode optimizes energy supply and redox balance, and indirectly improves phenanthrene bioavailability by modulating membrane structure and function. Full article

Impaired glucose metabolism elevates the risk of neurodegenerative diseases by activating the receptor for advanced glycation end products (RAGE), thereby promoting oxidative and endoplasmic reticulum (ER) stress that leads to neuronal apoptosis. C-phycocyanin (C-PC), a natural pigment–protein complex derived from algae, possesses potent antioxidant and antiglycation properties; however, its capacity to modulate RAGE-mediated neurotoxicity remains to be fully elucidated. In this study, we established a RAGE-driven neuronal injury model by exposing differentiated SH-SY5Y cells to advanced glycation end products (AGEs; 300 μg/mL). Pretreatment with C-PC (15–50 μmol/L) improved cell viability, preserved neuronal morphology, and attenuated AGEs-induced oxidative stress, as indicated by reduced intracellular reactive oxygen species and mitochondrial superoxide levels. Furthermore, C-PC inhibited activation of the PERK-CHOP pathway, and upregulated Bcl-2 while downregulating Bax, thereby preventing cytochrome c release and reducing caspase-9/3 activation as well as apoptotic DNA fragmentation. These neuroprotective effects of C-PC were comparable to those observed with the selective RAGE antagonist FPS-ZM1. In conclusion, our findings demonstrate that C-PC confers robust protection against AGEs-induced neuronal injury by suppressing oxidative and ER stress pathways downstream of RAGE activation, highlighting its potential as a natural modulator of the AGE–RAGE axis for the prevention or treatment of diabetes-associated neurodegeneration. Full article

Aux/IAA genes, functioning as transcriptional regulators downstream of auxin signaling, are essential for plant growth and development. However, their roles in fruit ripening remain largely undefined in strawberry. This study aims to elucidate the role of Aux/IAA genes in strawberry ripening. We identified 22 Aux/IAA family members and performed comprehensive spatiotemporal expression and hormone response analyses. Among them, FvIAA16 and FvIAA17 emerged as strong candidates associated with fruit ripening. Transient overexpression of FvIAA16 and FvIAA17 upregulated the expression of multiple ripening-related genes, leading to anthocyanin accumulation, soluble sugar enrichment, organic acid homeostasis, and furanone production. Dual-luciferase assays further demonstrated that both proteins robustly activated the promoters of ripening-related genes such as FvCHI and FvCHS. This activation was further enhanced by dimerization of the two proteins. Collectively, these findings reveal important regulatory functions of FvIAA16 and FvIAA17 in strawberry fruit ripening and offer valuable clues for further elucidating the molecular mechanisms underlying auxin-mediated ripening regulation. Full article

Rapeseed (Brassica napus) honey is a popular monofloral honey produced in Poland and is often suspected of pesticide-residue contamination due to the extensive use of pesticides in oilseed rape cultivation. Moreover, because of the presence of fatty acids, it can absorb hydrophobic polycyclic aromatic hydrocarbons (PAHs) that occur as environmental pollutants. Thus, the aim of the study was to assess the safety of rapeseed honey in terms of pesticide residues and PAHs contamination in relation to its functional properties, including antioxidant properties, polyphenol profile, protein content, and enzymatic activity. Local honey samples originating from Lublin (five) and Podkarpackie (five) Voivodeships were compared with five samples purchased from commercial sources. None of 58 pesticides, including carbamates, organophosphorus, organochlorines, pyrethroids, and neonicotinoids, were detected in the tested honey samples. All samples were also completely free of four major harmful PAHs legally limited in food (benzo[a]pyrene, benz[a]anthracene, chrysene, and benzo[b]fluoranthene). Among other PAH compounds, seven were detected accidentally in samples of various origins. The total phenolic content and antioxidant activity determined by DPPH^•, FRAP, and CUPRAC assays were relatively uniform among the groups studied. High-performance thin-layer chromatography (HPTLC) revealed characteristic fingerprints including kaempferol, ferulic acid, and caffeic acid, providing a specific profile that can be considered a marker of rapeseed honey authenticity and used to detect adulteration. Protein content ranged from 18 to 85 mg/100 g, remaining within the range typical for light honeys, while α-glucosidase activity was significantly reduced in commercial products, reflecting the effects of processing and storage. The study confirmed the high functional value and safety of rapeseed honey offered on the South-Eastern Poland market, which confirm the cleanliness of the bees’ habitat in terms of pesticide residues and PAHs pollution. Nevertheless, regular monitoring of pesticide residues and PAHs in honeys from agricultural areas remains advisable. Full article

Trifolium repens L. (white clover) is a widely distributed perennial legume, which is regarded as one of the most important forages for its high protein content and excellent palatability. Low temperature limits the distribution and productivity of white clover, thereby reducing its economic returns. WRKY transcription factors are key regulators in stress defense and are involved in multiple abiotic stress responses in plants. In this study, a cold inducible gene named TrWRKY41 was cloned from white clover. The TrWRKY41 protein is predominantly localized in the nucleus and functions as a hydrophilic, acidic protein. Under cold stress, the overexpression plants had significantly higher chlorophyll (CHL) and proline (Pro) contents, significantly increased activities of catalase (CAT), peroxidase (POD), and superoxide dismutase (SOD), and malondialdehyde (MDA) content significantly decreased. Compared to wild-type Arabidopsis thaliana, TrWRKY41-overexpressing plants exhibited better cold tolerance. In addition, target genes downstream of the TrWRKY41 transcription factor were predicted utilizing BLAST alignment and AlphaFold2 (version 0.2.0) software, the expression of six genes, including AtCOR47, AtCOR6.6, and AtABI5, was significantly up-regulated under cold stress. It suggests that TrWRKY41 may enhance cold tolerance in Arabidopsis by activating the ICE-CBF-COR cascade. This study provides candidate genes for research on enhancing the cold tolerance of white clover. Full article

The search for sustainable and health-promoting food ingredients has positioned microalgae as promising candidates for the development of functional products. Haematococcus pluvialis, a unicellular green microalga, is the richest natural source of astaxanthin, a carotenoid with outstanding antioxidant, anti-inflammatory, and neuroprotective properties. In addition to astaxanthin, H. pluvialis provides high-value proteins, essential fatty acids, polysaccharides, and vitamins, which expand its potential applications in the food sector. This review compiles current knowledge on the biology and physiology of H. pluvialis, with emphasis on cultivation strategies, environmental stress factors, and biotechnological tools designed to enhance bioactive compound production. Advances in extraction and purification methods are also discussed, contrasting conventional solvent-based approaches with emerging green technologies. The integration of these strategies with biomass valorization highlights opportunities for improving economic feasibility and sustainability. Applications of H. pluvialis in the food industry include its use as a functional ingredient, natural colorant, antioxidant, and stabilizer in bakery products, beverages, meat analogs, and emulsified systems. Evidence from in vitro, in vivo, and clinical studies reinforces its safety and effectiveness. Looking ahead, industrial perspectives point to the adoption of omics-based tools, metabolic engineering, and circular economy approaches as drivers to overcome current barriers of cost, stability, and regulation, opening new avenues for large-scale applications in food systems. Full article

The development of a fibrous-structured meat alternative that can perfectly mimic the tribology of the meat is considered to be extremely challenging. In this study, a bottom-up technique, wet spinning, was used to produce a fiber-like structure similar to muscle fiber. Different protein concentrations (0% to 16%) of wheat protein, pea protein isolates, and sodium alginate (2%) were used as an emulsifier and compared with the conventional meat (longissimus dorsi muscle) from a barrow in terms of physicochemical (pH, color, moisture content, cooking loss), textural (Texture profile and Warner–Bratzler Shear Force), and sensory parameters. The results from the study showed that the ratio of protein concentration significantly affected the solution behavior, leading to change in the spinnability of solution. The combined protein formulations displayed by a greater range of physicochemical and textural properties, especially hardness and WBSF, ranged from 22 N to 32.20 N and 4.26 to 4.71 kg/cm² in comparison to each other (p < 0.05). However, principal component analysis has shown that the overall profiling was significantly different than that of conventional meat (p < 0.05). The overall results suggested that the blend of wheat protein and pea protein isolate shows great potential for preparing a variety of structured meat alternatives by optimizing the concentration based on the desired product profiling. Full article

The domesticated silkworm, Bombyx mori, is a highly valued biodiversity and economic asset, acclaimed for its silk production, besides making important contributions to various scientific disciplines. However, the sericulture industry faces ongoing threats from bacterial and viral infections, which severely impact silkworm health and silk yield. This review provides a comprehensive overview of the innate immune response of B. mori against bacterial and viral pathogens, emphasizing the fundamental molecular and cellular defense mechanisms. We explore the humoral and cellular immune response using antimicrobial peptides (AMPs), pattern recognition receptors (PRRs) like peptidoglycan recognition protein (PGRP), and glucan recognition protein (GRP), which activate canonical signaling pathways. The review further highlights the molecular mechanisms underlying the silkworm’s defense against viruses, incorporating RNA interference (RNAi), apoptosis, and distinct signaling pathways such as Toll and Imd, JAK/STAT, and STING. We also discussed the viral suppression strategies and modulation of host metabolism during infection. Furthermore, the review explores the recent use of CRISPR-Cas gene editing to enhance disease resistance, presenting a promising avenue for mitigating pathogen-induced losses in sericulture. By elucidating these mechanisms, the work provides a synthesis that is critical in terms of developing particular interventions and developing more resistant silkworm strains to ensure that the industry of sericulture becomes viable and productive. Full article

Wheat (Triticum aestivum L.) is a key crop in Spain, especially in Castilla and León Region. However, there are few studies evaluating predictive models based on spectral indices and multivariate analysis to estimate yield in direct seeding (DS) and conventional seeding (CS) systems. This study addresses this need by implementing a split-plot experimental design in the city of Palencia, Spain, analyzing crop physiological data and nine spectral indices derived from multispectral aerial images captured by drones. The analysis included multivariate techniques such as Principal Component Analysis (PCA) and Random Forest (RF), supplemented with statistical tests, ROC curves, and prediction analysis. The results showed that the RF model successfully classified treatments with 93.75% accuracy and a Kappa index of 0.875, highlighting performance, nitrogen, and protein as key variables. Among the vegetation indices, the Soil-Adjusted Vegetation Index (SAVI) and the Advanced Vegetation Index (AVI) were the most relevant in the flowering stage, with ROC curve values of 0.7778 and 0.8025, respectively. Spearman’s correlations confirmed a significant relationship between these indices and key physiological variables, allowing to distinguish between DS and CS systems. The RF-based prediction model for performance showed R² values above 91% in the indices with the highest correlation. However, predictive capacity was higher in DS, suggesting that conditions inherent in non-mechanized handling significantly influence model performance. This highlights the importance of using non-destructive procedures to estimate production, enabling the development of adaptive and sustainable strategies that contribute to efficient agricultural production, since it is possible to anticipate crop yields before harvest, optimizing resources such as fertilizers and water. Full article

Microalgae of the genus Nannochloropsis are known for their ability to accumulate large amounts of lipids, particularly triacylglycerides (TAGs), when exposed to nitrogen-limiting conditions. This trait makes them promising candidates for biofuel production. While previous studies have used transcriptomics and metabolomics to explore how these organisms respond to nutrient stress, the role of post-translational modifications—especially protein phosphorylation—remains poorly understood. To address this gap, we conducted a comprehensive analysis of protein phosphorylation events in Nannochloropsis oceanica under both nitrogen-replete and nitrogen-depleted conditions over a time-course experiment. Using mass spectrometry-based phosphoproteomics, we identified 1371 phosphorylation sites across 884 proteins. Temporal clustering of these phosphorylation events revealed two distinct regulatory phases: an early response aimed at conserving nitrogen resources, and a later phase that promotes lipid accumulation. Notably, we identified 11 phosphorylated proteins associated with the Target of Rapamycin (TOR) signaling pathway, suggesting that this conserved regulatory network plays a key role in coordinating the cellular response to nitrogen deficiency. By integrating our phosphoproteomic result with previously published transcriptomic and metabolomic datasets, we provide a more complete view of how N. oceanica adapts to nitrogen stress at the molecular level. This systems-level approach highlights the importance of protein phosphorylation in regulating metabolic shifts and offers new insights into engineering strategies for enhancing lipid production in microalgae. Full article

The Elche palm grove (Spain) produces large surpluses of fresh date fruits due to low industrial processing and strict market standards. This exploratory study assessed the potential of these fruits as sustainable ingredients through the production of freeze-dried date flour and its green hydroethanolic extracts. Computer vision analysis of nine local cultivars (D1–D9) revealed broad chromatic and phenotypic diversity. Mineral and heavy metal analyses in the flour indicated high nutritional value and overall safety: D8 was richest in Mg (1.23 mg/g), P (0.78 mg/g), Fe (15.32 mg/kg), Zn (9.20 mg/kg), Cu (5.22 mg/kg), and Se (68 µg/kg), while D4 showed the highest K (22.1 mg/g) and D1 the highest Ca (1.94 mg/g). Lead and cadmium were highest in D8 and arsenic in D1, although all values remained within the regulatory limits. Hydroethanolic extracts exhibited remarkable compositional variability: D4 and D5 had the greatest carbohydrates (737.70 ± 55.79 mg/g DM), D8 and D9 the highest proteins (up to 40.31 ± 1.33 mg/g DM), and D2 and D8 the highest carotenoids (up to 36.44 ± 1.55 μg/g DM). D8 also showed the highest phenolics (13.98 ± 2.93 mg GAE/g DM) and antioxidant capacity. Cytotoxicity assays in Caco-2 cells showed no significant effects up to 1000 µg/mL. These preliminary findings suggest that green-extracted date fractions may combine nutritional richness, antioxidant potential, and biological safety, providing a basis for future studies on their application as natural and sustainable food ingredients. Full article

Fibronectin (FN) is a key mechanoresponsive glycoprotein within the extracellular matrix (ECM) that contributes to the assembly of a dynamic fibrillar network that is important for maintaining tissue structure and mediating cellular signaling. In this review, we delineate the molecular mechanisms underlying FN’s role in barrier restoration, ECM remodeling, and stem cell niche regulation, functions that inform its applications in both regenerative medicine and cosmetic science. In biomedical contexts, FN is recognized as a valuable biomarker for numerous diseases, a promising therapeutic target, and a functional component of biomedical material matrices. FN is involved throughout the skin repair process, making it a physiologically active ingredient for cosmetic anti-aging treatments, alleviating sensitive skin conditions, and enhancing cutaneous immunity. This review also addresses significant translational challenges associated with FN research, including recombinant protein production and rational peptide design, and suggests avenues for future work. Ultimately, studies on FN highlight the complexity of ECM biology and lay the groundwork for innovative approaches to advancing human health and developing new cosmetic treatments. Full article

Gastrointestinal strongyle infections are a common challenge in dairy goat farming, potentially impacting animal health and milk production. We, therefore, conducted a study to evaluate the efficacy of pour-on eprinomectin (EPM) in early-lactating dairy goats naturally infected with gastrointestinal strongyles and to verify the related effects on milk yield and quality. A total of 42 pluriparous Camosciata delle Alpi goats, from two farms (F1 and F2), were involved in the trial. In each farm, the goats were divided into two groups: untreated (CONTROL) or treated (EPM, 1 mg/kg BW). Following the treatment, faeces were individually collected weekly for one month, subjected to copromicroscopic analysis, a faecal egg count reduction (FECR) test, and coproculture; according to the same time schedule, individual milk yield was recorded, and individual milk samples were collected and analysed (fat, protein, lactose, and somatic cell count). Data were statistically analysed by a mixed-model procedure for repeated measures over time. The low efficacy of EPM was demonstrated at all experimental times; overall FECR percentages (90% CI lower and upper bounds) were 39.00% (30.12–50.53) for F1 and 38.82% (30.08–50.10) for F2. Coprocultures allowed the identification of larvae of the genera Haemonchus, Teladorsagia, and Trichostrongylus. Goats treated with EPM showed a lower prevalence of Teladorsagia and Trichostrongylus larvae, and higher prevalence of Haemonchus larvae, compared with CONTROL goats (p < 0.001). The treatment did not significantly improve milk yield or overall milk composition. Full article

Background: Skeletal muscle aging is characterized by impaired myogenic differentiation, disrupted circadian rhythms, elevated oxidative stress, and mitochondrial dysfunction. Rutin, a natural flavonoid with antioxidant properties, has been suggested to mitigate aging processes; however, its effects on circadian regulation and muscle homeostasis remain unclear. Methods: In vitro, differentiated C2C12 myotubes were treated with D-galactose (D-gal, 20 g/L) with or without rutin (20 μM). In vivo, C57BL/6 mice were supplemented with rutin (100 mg/kg b.w.) via oral gavage in a D-gal-induced aging mouse model (150 mg/kg b.w., i.p.). Results: D-gal induced cellular senescence, impaired myogenic differentiation, disrupted circadian oscillations, increased oxidative stress, and compromised mitochondrial function. Rutin treatment restored myotube formation, enhanced circadian rhythmicity of differentiation-related genes, and corrected the antiphase patterns of Per2 and Rorc. It also reduced reactive oxygen species and malondialdehyde levels; increased superoxide dismutase, catalase, and glutathione peroxidase activity; improved ATP production and membrane potential; and decreased mitochondrial oxidative aging, as confirmed by pMitoTimer imaging. Furthermore, rutin reinstated the rhythmic expression of oxidative phosphorylation proteins and Pgc1α. In vivo, rutin supplementation enhanced muscle performance (prolonged hanging time) and oxidative capacity, particularly at night (ZT14–ZT16), without altering muscle fiber-type distribution, and normalized circadian rhythmicity of core clock genes. Conclusions: Rutin attenuates D-gal-induced cellular senescence by modulating circadian rhythms, reducing oxidative stress, and improving mitochondrial function. Importantly, its in vivo effects on muscle performance and circadian regulation suggest that rutin is a promising therapeutic strategy to counteract skeletal muscle aging and sarcopenia. Full article