Search Results (646)

Ferroptosis, a type of iron overload-induced cell death, is involved in diabetes-induced testicular dysfunction. Hence, this study was designed to investigate, for the first time, the impact of lipoxin A4 (LXA4) administration on testicular tissue in diabetic rats and explore its probable role in regulating ferroptosis in comparison with the standard ferroptosis inhibitor (ferrostatin-1, Fer-1). Albino rats of Wistar strain were divided into a control group, a type II diabetes mellitus (DM) group, a DM + Fer-1group, and a DM + LXA4 group. Serum levels of iron, insulin, glucose, total cholesterol, triglycerides, and testosterone were assayed. Testicular tissue markers of oxidative stress, ferroptosis, and inflammation were also assessed by different methods. Our results confirmed diabetes-induced testicular injury and disruption of its function via inducement of ferroptosis, but this was ameliorated with LXA4 and Fer-1 administration. However, Fer-1 showed a greater protective effect compared to LXA4 under the conditions of this study. We concluded that LXA4 partially secured the testicular tissue of diabetic rats against ferroptosis via augmenting the antioxidant Nrf2/SLC7A11/GPX4 pathway. Therefore, LXA4 may have a possible protective effect on the testicular tissue of diabetic patients. Full article

Cultivation substrate critically affects the quality of Tremella fuciformis. Five substrates, including cottonseed hulls (MZKs), Machilus pauhoi Kanehira sawdust (BNM), lotus seed hulls (LZKs), Corethrodendron scoparium sawdust (HB), and palm fiber (ZL), were evaluated for their effects on agronomic traits, nutritional composition, texture, and taste characteristics. Untargeted metabolomics was applied to elucidate substrate-associated metabolic variations, and polysaccharide monosaccharide composition was quantitatively analyzed. The results showed that the BNM group exhibited the highest fresh weight, whereas the LZK group presented the highest dry weight and crude polysaccharide content. The ZL group displayed the greatest ear piece thickness and fruiting body elevation. Higher protein contents were observed in the ZL and LZK groups, with no differences in crude fiber content. Texture analysis indicated that hardness was highest in the LZK group, whereas the MZK group showed better springiness, cohesiveness, and chewiness. Regarding taste characteristics, the MZK group exhibited the strongest sweetness, the LZK group showed a markedly higher bitterness, and umami levels were comparable across all groups. Metabolomic analysis revealed that substrate-induced variations in amino acids, saccharides, and taste-related metabolites were significantly associated with nutritional quality and taste attributes of T. fuciformis. Polysaccharides of fruiting bodies cultivated on the five substrates consisted of six monosaccharides, with composition ratios similar to those of spore extracellular polysaccharides; among them, differences in glucuronic acid (GlcA) proportion represented a key indicator distinguishing fruiting body polysaccharides from spore polysaccharides. This study revealed the metabolic basis and polysaccharide composition underlying substrate-dependent quality of T. fuciformis, supporting substrate optimization for high-quality production. Full article

This study developed an active packaging material by incorporating tea tree oil (TTO)-loaded lotus stalk biochar (BC@TTO) into a chitosan (CS) matrix. Biochar was prepared from lotus stalks via pyrolysis at 600 °C and characterized, revealing a mesoporous structure with a specific surface area of 35.9 m²/g. Adsorption studies demonstrated that BC exhibited high affinity for TTO, following pseudo-first-order kinetics and the Langmuir isotherm model, with a maximum adsorption capacity of 295.6 mg/g. Chitosan-based composite membranes with varying BC@TTO contents (1–7 wt%) were fabricated by solution casting. The incorporation of BC@TTO significantly enhanced the tensile strength, elongation at break, barrier properties (water vapor and oxygen), and antioxidant/antibacterial activities of the membranes, with optimal performance observed at 3 wt% loading. However, higher loadings led to filler aggregation, reduced transparency, and compromised mechanical properties. In vitro release studies indicated that TTO release followed the Avrami model, suggesting a diffusion-controlled mechanism. Preservation tests on blueberries showed that the CS-3BC@TTO membrane effectively reduced weight loss and maintained fruit quality during storage. This work presents a promising strategy for designing bioactive packaging materials with sustained release functionality for food preservation applications. Full article

The Hyakuzahōdan Kikigakishō (百座法談聞書抄, hereafter Hyakuza 百座), compiled in the late Heian period, is an important Buddhist document that records a hundred-day lecture series on the Lotus Sutra (法華経). While previous scholarship has recognized the constructed nature of the text as a kikigaki (聞書), it has predominantly focused on content analysis, implicitly treating the text as a transparent window into the actual preaching event. To move beyond this limitation, this study proposes the analytical framework of dual performativity and, drawing on Diana Taylor’s theory of the archive and the repertoire, reexamines the text’s generative logic and political implications. This study argues that the Hyakuza embodies two interrelated forms of performance: first, the performativity of the hōdan (法談) as a live ritual, understood as a repertoire performance that constructs immediate authority through body, voice, and situational dynamics; second, the performativity of the kikigaki as textual construction, understood as an archival performance that transforms the ephemeral oral event into an authoritative, transmissible text through formulaic rhetoric, localized adaptation, and systematic arrangement. Integrating methodologies from textual history, rhetorical analysis, ritual theory, and intellectual history, this study demonstrates that the Hyakuza is not a neutral transcript of sermons but a meticulous, intentional act of writing with two fundamental aims: on a cultural level, to hierarchically integrate shinbutsu shūgō (神仏習合) through narrative appropriation; on a social level, to symbolically bind Buddhist merit with the institutional identities of aristocrats such as naishinnō (内親王), ultimately serving the self-affirmation internal cohesion, and cultural demarcation of the elite community from the masses, while simultaneously contributing to the state’s project of constructing a unified ideology in the late Heian period. By examining both cross-civilizational universal logic and specific historical context, this study reveals how the Hyakuza’s dual performativity produces and categorizes knowledge narratives while embedding political power dynamics, offering a critical path for the study of kikigaki-genre literature from discourse analysis to politics of textuality. Full article

Background: The DOF transcription factor family is involved in plant growth, development, and stress responses, but systematic comparative genomics studies across legume species are lacking. Methods: We identified the whole genome of the DOF gene family of five legume plants: Medicago truncatual (43), Cicer arietinum (43), Phaseolus vulgaris (44), Glycine max (79), and Lotus japonicus (32). Genome-wide identification of DOF genes was performed in five legume species, followed by phylogenetic analysis, gene structure characterization, duplication event identification, promoter element prediction, synteny analysis, and expression pattern profiling. Results: Phylogenetic comparison with Arabidopsis thaliana (47) and Oryza sativa (37) classified them into four subfamilies (Groups I–IV). The five legumes all had no more than 30% members of the subgroup. The same subfamily has similar protein structures and gene structures, and most of its members have motif1, with most plants having more than 30% of genes intronic. Gene duplication events were evenly distributed among the members of the DOF gene in all five legumes, and played an important role in its evolution. Moreover, the majority of the DOF genes showed tissue specificity in the five legumes, with most of these members being upregulated in flowers. Additionally, expression pattern analysis under abiotic stress in soybean revealed that members of different subfamilies exhibit divergent expression dynamics under salt, alkali, and cold stresses. The DOF gene family in legumes expanded primarily through segmental duplication and evolved under purifying selection. Conclusion: The subfamily-specific responses to abiotic stress and tissue-specific expression patterns provide candidate gene resources for functional studies aimed at improving stress tolerance and agronomic traits in legume crops. Full article

ABC transporters (ATP-binding cassette transporters) constitute one of the largest known protein families and are widely distributed in plants. Their primary function involves utilizing energy derived from ATP hydrolysis to transport substrates across membranes against concentration gradients. These transporters play crucial roles in the translocation and accumulation of metabolites, stress tolerance, disease resistance, and plant defense. Lotus is an important traditional Chinese medicinal herb and contains active ingredients primarily composed of secondary metabolites, whose transport and accumulation require the involvement of ABC transporters. However, the function of these ABC transporters remains unexplored in lotus. In this study, 122 ABC transporter genes were predicted within the lotus genome. We identified 1~15 conserved motifs among the NnABC proteins and most of them were stable proteins predominantly located on the plasma membrane with ExPASy-ProtParam, ProComp and WoLF PSORT analysis. Phylogenetic tree analysis revealed that the lotus ABC transporter gene family could be divided into eight subfamilies, from ABCA to ABCI, and the evolution was predominantly driven by purifying selection. Comparative transcriptome analysis between the cultivar ‘Yindu Zhimi’ with orange-reddish stamen and ‘Weishan Hong’ with yellowish stamen, along with quantitative real-time PCR results, showed that the NnABCG25 gene is highly specifically expressed in the orange-reddish stamen. Molecular docking demonstrated that NnABCG25 has a stable affinity for lycopene, β-carotene and β-apocarotenal, suggesting its potential involvement in the transport of carotenoids in the stamen. These findings expand our understanding of the role of ABC transporters in the transport and accumulation of carotenoids, as well as providing a valuable reference for research on the ABC transporter gene family in other plants. Full article

Breast cancer represents a persistent global health burden, marked by extensive molecular heterogeneity and frequent therapeutic resistance in aggressive subtypes, particularly triple-negative breast cancer (TNBC). These clinical challenges underscore the urgency for alternative therapeutic strategies. Bioactive alkaloids isolated from Nelumbo nucifera, especially the bisbenzylisoquinoline compounds liensinine (LIE), isoliensinine (ISO), and neferine (NEF), have emerged as promising candidates due to their ability to disrupt oncogenic signaling pathways and inhibit malignant cellular transformation. The present study conducted a systematic investigation of LIE, ISO, and NEF across multiple breast cancer cell lines, including highly aggressive TNBC models. Results revealed potent growth-inhibitory effects mediated through apoptosis induction and cell cycle arrest at both the G1 and G2/M phases. Furthermore, transcriptomic profiling and molecular analysis identified LIE as a principal effector, driving extensive transcriptional reprogramming and targeting the MAPK and mTOR pathways as core regulators of its anti-cancer efficacy. Collectively, these findings define a mechanistic framework for the anti-cancer potential of N. nucifera-derived alkaloids and provide a compelling foundation for their development as therapeutic candidates for advanced breast cancer. Full article

Lotus leaf provides unique nutritional properties to the traditional Chinese dish Jiao Hua Ji. However, its functional polysaccharides remain inadequately characterized. This study evaluates the physicochemical properties and hypoglycemic effects of lotus leaf polysaccharides in Jiao Hua Ji. Ultrasonic-assisted enzymatic extraction significantly improved the yield of polysaccharides to 10.35 ± 0.39%. The yield of the polysaccharides as well as uronic acid content demonstrated a strong correlation with the bioactivity. FTIR analysis confirmed the characteristic infrared spectral features associated with glucans. Four polysaccharides were purified and characterized as 719 kDa (Glc/Gal/Ara 98.91:0.44:0.65), 1010 kDa (Glc/Gal/Ara 98.43:1.18:0.39), 447 kDa (Glc/Gal/Ara 97.17:2.02:0.82), and 327 kDa (Glc/Gal/Ara 97.54:2.06:0.4). The purified polysaccharides exhibited enhanced inhibition of α-amylase, positively correlating with molecular weight and glucose content. Molecular docking studies revealed that the polysaccharide successfully occupies the hydrophobic pocket of α-amylase through hydrogen bonds, with a low binding energy of −6.548 kcal/mol. Notably, the purified polysaccharide significantly improved glucose utilization by 157.5% without cytotoxicity. This study may provide a foundational basis for the application of Jiao Hua Ji in hypoglycemic dietary intervention. Full article

This review summarizes scientific advances about the sonochemical synthesis of starch nanoparticles (St-NPs) for the food industry, as well as nutraceutical and drug delivery applications. High-intensity ultrasonication (HIU) has been explored as a versatile and environmentally friendly alternative to conventional methods for synthesizing St-NPs with high yields (>90%), controlled size (~100 nm), and minimal effluent generation. Thus, HIU has been explored (pre- or post-treatment) to mitigate the inherent disadvantages (high-cost, low yields, and environmental impact) of hydrothermal gelatinization, acid/alkaline hydrolysis, enzymatic hydrolysis, enzyme branching, water-in-oil and oil-in-water emulsions, non-solvent nanoprecipitation, extrusion, high-pressure homogenization, high-energy milling, and cold plasma. Conventional sources of starch (corn [normal, waxy, high-amylose] and potato) and other unconventional sources (tubers [cassava, yam, malanga], seeds and grains [sorghum, barley, quinoa, lotus], breadfruit, pinhao seed, Araucaria angustifolia) have been subjected to single or assisted sonochemical protocols to obtain St-NPS with unique structural, physicochemical, and technological properties. The physical–mechanical effects of ultrasonication (cavitation, heat, and pressure) directly promote surface functionalization (i.e., esterification, pore formation) and impact the St-NPS’s particle size, double-helix structure, enzymatic-resistance properties, crystallinity, and intra- and intermolecular arrangements. Pickering additives in food systems, colloids in beverages, nanocomposites in biofilms for food packaging, and nanocarriers for drug and nutraceutical delivery (oral and transdermal) have been the most reported applications. Full article

Browning is the major physiological cause of quality loss in lotus root. This study explored the effects of temperature (4 °C, 25 °C, 35 °C) or ethylene (ET) on quality, especially browning, as well as polyphenol and starch metabolism in lotus root. Low temperature (4 °C) reduced browning and color changes (L*, a*), while retaining water and vitamin C (Vc) content. ET maintained Vc and soluble protein, while high temperature (35 °C) promoted total soluble solids (TSS) and soluble sugar accumulation. ET or 35 °C upregulated polyphenol metabolism-related genes including NnPAL1/4, NnCHS1, NnF3H and NnANR, increased total phenolic and flavonoid content, and enhanced antioxidant capacity. Moreover, 35 °C increased PAL activity, and ET also upregulated NnUGT88B1. Furthermore, 4 °C downregulated NnGBE1-1/2, promoted starch accumulation, while ET upregulated NnSSI, downregulated NnGBE1-1/2, and delayed starch decline. Meanwhile, ET elevated NnETR and NnEBF1-2 and mediated ethylene signaling transduction. In conclusion, 4 °C storage was optimal for delaying browning and starch metabolism of lotus root. Meanwhile, ET treatment or 35 °C were more beneficial to obtain more phenolics and flavonoids. Full article

Ziziphus lotus (L.) Lam., an extremophyte shrub native to the Mediterranean basin, yields underexplored fruits as a source of therapeutic agents. This study combined in vitro and in silico approaches to evaluate the antioxidant potential of Z. lotus fruits and predict their potential to inhibit xanthine oxidase (XO), a key enzyme in reactive oxygen species generation and oxidative stress-related pathologies. The ethyl acetate extract from the hydroalcoholic macerate was enriched in total phenolics (281.33 ± 1.5 μg GAE/mg) and flavonoids (127.26 ± 5.89 μg RE/mg) and displayed remarkable effects against the ABTS^•+ radical cation (IC₅₀ = 18.49 ± 1.47 μg/mL) and phenanthroline reducing power (A_0.5 = 8.38 ± 0.69 μg/mL), together with measurable xanthine oxidase inhibition (IC₅₀ = 170.4 ± 5.90 μg/mL). The compounds tentatively identified by full-scan UHPLC-QtoF-HRMS were docked against XO (PDB ID: 3NVY), with phytosphingosine (−8.5 kcal/mol) and rutin (−8.3 kcal/mol) exhibiting the strongest binding affinities, forming favorable predicted interactions with critical catalytic residues, followed by 6‴-feruloylspinosin, 3′,5′-di-C-β-glucopyranosylphloretin and hexadecasphinganine (ranging from −7.8 to −7.6 kcal/mol). Predictive structure–activity relationships were also observed. These results provide insights into the antioxidant potential of Z. lotus phytochemicals and highlight the value of this extremophile plant as sustainable resource for phytotherapy and the management of oxidative stress-related diseases. Full article

This study utilized network pharmacology, bioinformatics, along with machine learning to investigate the multi-target synergistic anti-cancer mechanisms of three edible medicinal plants (EMPs)—mulberry leaf, lotus leaf, and sea buckthorn—against oral and esophageal squamous cell carcinomas (OSCC and ESCC). We identified potential active constituents and their targets through mining Traditional Chinese Medicine Systems Pharmacology (TCMSP) and Swiss Target Prediction databases. Concurrently, integration with differential expression profiles and co-expression modules identified crucial intersection targets between the EMPs and these two cancers. Subsequent machine learning algorithms and cross-cancer analysis consistently identified Matrix Metalloproteinase-1 (MMP1) as a critical hub gene. Its overexpression is closely associated with tumor invasion and metastasis. Molecular simulations revealed stable binding interactions between active constituents from three EMPs and hub proteins. Furthermore, research on immune cell infiltration suggested that the active components of three EMPs may impact the tumor immune microenvironment in both OSCC and ESCC through the regulation of pivotal gene expression. Collectively, this work systematically elucidates the molecular basis underlying the multi-target, multi-pathway synergistic anti-cancer effects of these EMPs, providing a theoretical foundation for developing natural drugs against these squamous cell carcinomas. Full article

Due to its advantages in specific surface area and oxygen-containing functional groups, biochar was often utilized for water pollution control. In this study, biochar was prepared from three types of wetland plants—Lotus Leaf, Arundo donax L., and Canna indica L. through slow pyrolysis. This biochar was utilized to adsorb Cr(VI) from wastewater, and the adsorption performance of the biochar under different pyrolysis temperatures and KOH modification ratios was investigated. The experimental results of biochar preparation demonstrated that under the pyrolysis of 500 °C and the lotus leaf powder/KOH mass ratio of 1:3, the prepared biochar (LBC-500(1:3)) exhibited the optimal adsorption capacity for Cr(VI) at a concentration of 50 mg·L⁻¹, with an adsorption capacity reaching up to 27.88 mg·g⁻¹. The optimal pH for Cr(VI) adsorption by LBC-500(1:3) was 3, with an adsorption capacity of 32.14 mg·g⁻¹ at this pH. When the dosage amounted to 60 mg, LBC-500(1:3) demonstrated its highest adsorption capacity for Cr(VI), achieving a maximum of 19.39 mg·g⁻¹. When the initial concentration peaked at 80 mg·L⁻¹, the adsorption capacity was able to attain a value of 34.80 mg·g⁻¹. Characterization analyses of the biochar prior to and subsequent to adsorption were conducted to elucidate the adsorption mechanisms of biochar for Cr(VI). The results revealed that the primary removal mechanisms of LBC-500(1:3) for Cr(VI) were coordination, electrostatic adsorption, and pore filling. The analysis of adsorption kinetics and isotherms revealed that the biochar predominantly adsorbed the Cr(VI) through monomolecular layer chemisorption. Adsorption thermodynamics results demonstrated that the adsorption process of the biochar was a spontaneous endothermic reaction. This study provides new insights and technical support for water pollution control, which holds significant environmental importance and application value. Full article

Pollen is one of the main food sources for honeybees. The honeybee gut microbiota plays a crucial role in maintaining digestive function and host health during long-term coevolution. While the consumption and utilization of pollen have been extensively studied, there is limited information about the effects of pollen on the gut microbiota of Apis cerana. In this study, we used 16S rRNA amplicon sequencing to evaluate the effects of four natural pollens (oilseed rape pollen, camellia pollen, lotus pollen and buckwheat pollen) and two pollen substitutes (Diet 1 and Diet 2) on the hindgut microbiota of newly emerged A. cerana worker bees, following feeding periods of 5, 10 and 15 days. The results showed that Firmicutes and Proteobacteria are dominant in the gut microbiota of A. cerana. A. cerana workers fed with pollen diets had a higher diversity of gut microbiota than those fed with pollen substitutes. There have been significant differences in the gut microbiota structure and relative abundance of the core microbial community among A. cerana workers supplied with different diets. Our results confirm that gut bacterial communities of A. cerana can be influenced by pollen diets and may play an important role in host adaptation. Full article

Fragrance lotus (Nymphaea hybrid) is a tropical interspecific cultivar characterized by large flowers and high scent intensity, offering dual potential for ornamental commerce and natural fragrance extraction. Floral scent determines both economic value and pollinator attraction, yet the biosynthetic organs and metabolic routes remain undocumented. To fill this gap, single flowers of the high-aroma cultivar ‘Eldorado’ at full anthesis were dissected into petal (PE), stamen (ST) and pistil (PI); each organ was subjected to untargeted LC-MS/MS metabolomics and Illumina RNA-seq. Organ-specific gene–metabolite co-expression networks were constructed by pairwise integration of transcript and metabolite matrices. All three organs formed distinct clusters in principal-component space. Compared with PE, 6221, 3352 and 5891 differentially expressed genes (DEGs) together with 30, 24 and 39 differentially accumulated metabolites (DAMs) were identified in ST, PI and PE, respectively. The phenylpropanoid biosynthesis pathway (map00940) was the only route simultaneously enriched at both transcript and metabolite levels; 59 DEGs mapped to this pathway co-linearly with three scent-related DAMs. ST contained the highest concentration of scent-active volatiles; phenylalanine ammonia-lyase (PAL), cinnamate-4-hydroxylase (C4H), 4-coumarate-CoA ligase (4CL) and benzaldehyde reductase (BAR) were all significantly up-regulated in this organ, driving the accumulation of p-coumaric acid that is subsequently channeled into benzyl alcohol via side-chain cleavage and BAR-mediated reduction, thereby generating the characteristic fragrance of Nymphaea. This study provides the first organ-level resolution of scent biosynthesis and metabolic flux partitioning in fragrance lotus, furnishing molecular targets for directed aroma improvement and efficient natural fragrance extraction. Full article