Search Results (3,572)

Previous studies on velvet antler processing have mainly evaluated single techniques, and systematic comparisons of processing combinations are limited. This study investigated the effects of different processing combinations on the nutritional composition and physicochemical properties of velvet antler from red deer and sika deer. A 2 × 2 factorial design was applied: Blood-Retained vs. Blood-Removed and Boiled/Fried (zhuzha; no deep-frying) vs. Vacuum Freeze-Dried. In this study, Boiled/Fried was treated as a single processing method. The four processing combinations were analyzed as independent groups using one-way ANOVA. Additionally, two-way ANOVA was conducted to evaluate the main effects of pretreatment, dehydration method, and their interaction on the measured indices. To account for species background, a three-way ANOVA (species × pretreatment × dehydration) was further conducted for key indices. Moisture, crude protein, ash, and crude fat contents were determined. All composition-related indices were evaluated on both wet-weight and dry-weight bases to distinguish moisture-driven concentration or dilution effects from processing-related retention changes. Principal component analysis (PCA) and orthogonal partial least squares discriminant analysis (OPLS-DA) were conducted for multivariate evaluation. Spearman’s rank correlation was used for association analysis, and Pearson’s correlation with linear regression was applied to quantify linear relationships (reported as r). Freeze-drying significantly reduced moisture content (p < 0.01) and increased crude protein content (p < 0.05). PCA and OPLS-DA demonstrated clear compositional separation among the four processing combinations, with moisture and crude protein as the main contributors (cumulative explained variance > 83%). The effects of Blood-Retained and Blood-Removed treatments differed between species. Three-way ANOVA indicated significant species-dependent effects (e.g., species × pretreatment and or species × dehydration interactions), while the pretreatment × dehydration interaction was significant for TAAs. In the Boiled/Fried groups, total amino acid content (TAA) decreased with increasing moisture. In the Freeze-Dried groups, moisture was significantly negatively correlated with TAAs in the Blood-Retained treatment (Pearson r = −0.886, p < 0.05), whereas no significant correlation was observed in the Blood-Removed treatment (r = 0.429, p > 0.05). Wet- versus dry-basis comparisons indicated that some between-treatment differences were attributable to moisture-related concentration or dilution effects, whereas differences persisting on a dry basis more directly reflected processing-related nutrient retention. Processing combinations produced species-dependent effects in velvet antler. The three-way ANOVA supported species-dependent pretreatment effects and confirmed that the influence of blood retention or removal on amino acid outcomes was contingent on the dehydration regime (pretreatment × dehydration for TAAs). From an application standpoint, no single processing route is universally optimal across all quality attributes; freeze-drying provides a robust baseline, whereas the choice of blood retention or removal should be made in a target-oriented manner (e.g., physicochemical stability versus protein and amino acid retention) while accounting for species background and interaction effects. Therefore, these findings provide a scientific basis for improving product quality, processing efficiency, and standardization in China’s velvet antler industry. Full article

This study investigated the effects of dietary Bacillus cereus, administered alone or in combination with biofloc technology, on the growth performance, immune response, disease resistance, and intestinal microbiota of Litopenaeus vannamei. Shrimp fed diets supplemented with B. cereus, either directly or via biofloc systems, exhibited significantly increased final body weight and specific growth rate, together with a reduced feed conversion ratio compared with the control group. The expression levels of key hepatopancreatic immune-related genes, including lysozyme, prophenoloxidase, superoxide dismutase, Toll, immune deficiency, and Relish, were significantly upregulated in probiotic-associated treatments. Following challenge with Vibrio parahaemolyticus, cumulative mortality was markedly lower in all treatments involving B. cereus or biofloc compared with the control. Although alpha diversity indices were not significantly affected, beta diversity analysis demonstrated that supplementation frequency and delivery mode altered intestinal microbial community structure. The phyla Bacteroidota, Firmicutes, and Proteobacteria predominated across treatments, while members of Marinilabiliaceae and Shewanellaceae were enriched under probiotic-associated conditions, suggesting enhanced nutrient transformation potential. Co-occurrence network analysis further revealed increased microbial network complexity and positive interactions in probiotic and biofloc treatments, indicating improved community stability. These findings demonstrate that the synergistic application of B. cereus and biofloc technology enhances growth performance, immune capacity, and intestinal microbial resilience in intensive shrimp culture, and that supplementation strategy plays a critical role in optimizing probiotic efficacy. Full article

The Eastern Tropical Pacific (ETP) comprises several coral ecosystems, which are distributed across a variety of coastal zones and oceanic islands. In these ecosystems, reef fish play key roles in their functioning. In ETP, there is a paucity of studies that have evaluated fish functional diversity (FD) and compared oceanic and coastal systems from a predominantly trophic perspective. A comparative analysis was conducted on fish FD in seven coral ecosystems, encompassing three distinct environmental contexts: (1) Oceanic, (2) Coastal-influenced, and (3) Coastal. The hypothesis that FD varies spatially along this oceanic–coastal gradient is predicated on the premise that such variation is attributable to differences in disturbance regimes and environmental conditions. Our results show that not all functional α-diversity indices exhibited significant variation among zones. However, analysis of functional dominance, divergence, dispersion, and β-diversity analyses revealed clear spatial variation in functional structure, partially supporting expectations related to disturbance regimes across the oceanic–coastal gradient. These patterns may be indicative of increasing disturbance intensity, in conjunction with other interacting processes such as variability in larval supply, recruitment dynamics, and environmental conditions, including fishing pressure, sedimentation, nutrient inputs, and coastal upwelling. The findings of this study demonstrate the efficacy of functional diversity metrics in assessing reef fish responses to both natural and anthropogenic disturbances. In addition, the present study offers actionable insights with regard to the formulation of conservation and management strategies in the Mexican Eastern Tropical Pacific. Full article

The mycoheterotrophic plant Monotropa uniflora relies on fungal symbionts for carbon and nutrient acquisition. However, its interactions with other microbial groups, beyond ectomycorrhizal fungi, remain unexplored. Here, we characterized bacterial and fungal communities associated with M. uniflora across two compartments: ectomycorrhizospheric soil linked to the mycorrhizal network and the surface-sterilized lower stem endosphere. Microbial community composition was assessed using high-throughput amplicon sequencing of the bacterial 16S rRNA gene and the fungal ITS region. Fungal richness was consistently higher in ectomycorrhizospheric soil than in the stem endosphere, whereas bacterial alpha diversity showed no consistent differences between compartments. Multivariate analyses suggested compartment-associated patterns in both bacterial and fungal community composition. Ectomycorrhizospheric soil was dominated by saprotrophic fungal taxa and bacterial groups with predicted metabolic potential, including taxa associated with iron, sulfur and nitrogen cycling. In contrast, the lower stem endosphere was enriched in bacterial taxa commonly associated with anaerobic and nitrogen-related metabolisms. Functional predictions further suggested an increase of carbon fixation-related pathways in rhizosphere-associated bacterial communities. Together, these results indicate that M. uniflora is associated with distinct and structured microbial assemblages across soil and internal plant compartments, highlighting the predicted functional potential of bacterial communities in nutrient- and carbon-related processes in mycoheterotrophic plant–soil systems alongside fungal partners. Full article

Humic substances (HS), derived from the degradation of organic matter in terrestrial and aquatic systems, play critical roles in nutrient cycling, metal complexation, and soil fertility. This study investigates whether HS derived from Greek peaty lignite (leonardite) can bind Mo(VI), an essential micronutrient for nitrogen fixation and assimilation processes. Titration experiments showed that the addition of Mo(VI) to HS solutions decreased pH, indicating Mo(VI)–HS complexation via proton-release reactions. UV-Vis spectra revealed charge-transfer interactions without evidence of Mo reduction, while FTIR analysis confirmed that carboxylic, phenolic, and alcoholic groups participate in Mo(VI)–HS association as indicated by shifts in COO–, C=O, and O–H vibrations. The results demonstrate that HS can effectively complex Mo(VI), increasing its solubility and potentially enhancing its bioavailability in soils. These findings highlight the value of humic-rich materials such as leonardite in sustainable crop nutrition. Full article

Polyunsaturated fatty acids (PUFAs), especially the long-chain omega-3 fatty acids eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), are essential nutrients for aquatic organisms and play key roles in growth, reproduction, neural development, and immune function. In freshwater ecosystems and aquaculture systems, the availability of these lipids depends on complex interactions within aquatic food webs, where PUFAs are produced by primary producers and transferred to higher trophic levels. This review summarizes current knowledge on the biosynthesis, regulation, and trophic transfer of PUFAs in freshwater aquaculture food webs, with particular emphasis on interactions among microalgae, zooplankton, and fish larvae. The main biochemical pathways and regulatory mechanisms responsible for PUFA synthesis in microalgae are described, together with the environmental factors that influence their production. The role of zooplankton at an intermediate trophic level is discussed, highlighting their ability to retain, modify, and transfer dietary fatty acids to higher consumers. Finally, the capacity of freshwater fish larvae to synthesize and regulate long-chain PUFAs through key metabolic enzymes is examined, along with the influence of diet and environmental conditions on these processes. By integrating information from molecular, biochemical, physiological, and ecological studies, this review provides an overview of the mechanisms underlying PUFA production and trophic transfer in freshwater aquaculture food webs. Full article

Cellular homeostasis is a dynamic process which balances anabolic processes with catabolic and recycling processes. These processes require nutrients, which are converted to energy to fuel the complex interactions of intracellular signalling. Cellular health requires that, on average, energy input and energy requirements are matched. Cells contain a nutrient-sensing mechanism which controls the balance between anabolism and catabolism. Normal intracellular functions generate products which regulate signalling pathways, and health at a cellular level requires a fluctuation between relative nutrient abundance and relative nutrient scarcity. This allows clearance of damaged intracellular molecules and organelles. When nutrient supply exceeds cellular requirements, adaptations to intracellular signalling occur, resulting in energy being stored as glycogen in muscle and the liver and fatty acids in adipose tissue. Overfuelling and aberrant fuelling of mitochondria result in oxidative stress, which not only disrupts cellular homeostasis but can alter epigenetic expression, with intergenerational effects. If the recycling mechanisms of the cell are insufficient to clear metabolic products, apoptosis may result or expression of Damage-Associated Molecular Patterns (DAMPs) on the cell surface may occur, activating immunity and inflammation at a systemic level. Disrupted cellular signalling affects cells with different “professional” functions in different organs, and it is the mechanism which underlies the associations between chronic non-communicable diseases such as cancer, type 2 diabetes, cardiovascular disease, neurodegenerative disease, autoimmune diseases, and macular degeneration. Mitochondria are the controllers of energy production and are pivotal in cell signalling. Mitochondrial function governs health at cellular and organismal levels. This paper reviews the influence of nutrition on mitochondrial function, nutrient sensing, autophagy, insulin signalling, and apoptosis—the key pathways in cellular homeostasis. Full article

Cross-kingdom pathogenesis—human and animal pathogens colonizing and persisting in plants—is transforming our understanding of microbial ecology, food safety, and public health. This review translates incoming research that demonstrates plants as more than mute carriers to dynamic ecological interfaces where human and zoonotic pathogens, such as Salmonella enterica, Escherichia coli O157:H7, and Listeria monocytogenes, will adhere, internalize, and, in some cases, potentially evade host defenses. Such pathogens exploit evolutionarily conserved molecular processes like Type III secretion system 1 (TTSS), biofilm formation, quorum sensing, and small RNA-mediated immune sabotage that have allowed them to cross biological kingdom boundaries. To provide an entry point for pathogens, environmental conditions (e.g., contaminated irrigation water, manure application, wildlife access, and mechanical wounding) promote pathogen transfer to and penetration into plant tissues through stomata hydathodes above ground or roots below ground. Once inside, pathogens confront a range of plant immune responses, indigenous microbiota, and abiotic stresses such as UV radiation exposure, nutrient starvation, and osmotic fluctuations. Nonetheless, biofilm production, metabolic versatility, and virulence gene expression contribute to their persistence. Interactions with plant pathogens and microbiomes additionally shape colonization dynamics, for example, through co-survival and niche manipulation. With the acceleration of these processes due to climate change, urbanization, and intensified agriculture, cross-kingdom pathogenesis becomes a rising concern for One Health. Critical knowledge gaps, including seedborne transmission, microbiome engineering, and predictive modeling, are pointed out in the review along with emerging mitigation strategies, including point-of-care diagnostics and microbial biocontrol. In conclusion, this review advocates for interdisciplinary collaboration from microbiology, plant science, and One Health perspectives to predict and mitigate cross-kingdom threats to global food production. Full article

SHORT INTERNODE (SHI)-related sequence (SRS) transcription factors are plant-specific zinc-finger proteins increasingly implicated in growth and abiotic stress responses. Despite their diverse vital role in plants, they are largely unexplored in bread wheat. In this study, we identified 15 TaSRS genes and classified them into five homoeologous groups in the bread wheat genome. Each TaSRS protein consisted of conserved RING-like zinc-finger and IGGH domains. The synteny and phylogenetic analyses provided insight into the evolutionary divergence and conservation of TaSRS proteins. Promoter analysis revealed the presence of stress-responsive cis-regulatory elements along with various transcription factor binding sites, indicating their plausible roles in drought and salinity stress responses and signalling. Additionally, the predicted regulation of a few TaSRS genes through certain miRNAs involved in hormone and stress responses, plant development, and nutrient uptake suggested their diverse functions. In silico protein–protein interaction and gene ontology analyses further anticipated an association of TaSRS proteins with organ development and hormone and stress response. High-throughput transcriptomic profiling revealed differential expression of TaSRS genes across various vegetative and reproductive stages and abiotic stress conditions. The qRT-PCR analyses confirmed the stress-responsive role of TaSRS1-1D, TaSRS2-3D, TaSRS4-7A, and TaSRS5-7A under drought and salinity conditions. These results indicated the potential role of TaSRS genes in stress adaptation and opened up opportunities for their detailed functional characterization and applications in the development of salinity and drought resilience in crops. Full article

Castanopsis hystrix (C. hystrix) is one of the most dominant and ecologically important species in subtropical evergreen broad-leaved forests of China. Interactions between its root and rhizosphere microorganisms play a pivotal role in nutrient acquisition and in mediating plant response s to environmental stresses. In this study, high-throughput 16S ribosomal RNA (16S rRNA) sequencing combined with untargeted metabolomics was employed to systematically characterize the rhizosphere microbial community and root exudates in C. hystrix. The results showed that, compared with non-rhizosphere soil, bacterial diversity in the rhizosphere of C. hystrix was significantly reduced, while several specialized and potentially efficient taxa were selectively enriched, particularly Candidatus_Solibacter, Candidatus_Xiphinematobacter, and Candidatus_Koribacter, thereby reshaping a distinct rhizosphere-specific community structure. Metabolomic analyses further revealed that 129 metabolites were significantly enriched in the rhizosphere, including four major classes of compounds associated with plant stress resistance: lipids and lipid-like molecules, organoheterocyclic compounds, organic acids and derivatives, and phenylpropanoids and polyketides. The enrichment of these metabolites likely contributes substantially to stress tolerance in C. hystrix. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis identified six defense-related metabolic pathways, including pyrimidine metabolism, steroid biosynthesis, nucleotide metabolism, plant hormone signal transduction, ATP-binding cassette transporter (ABC transporters), and the biosynthesis of various plant secondary metabolites. Further correlation analysis and co-occurrence network analysis suggested that C. hystrix may potentially influence the enrichment of beneficial microorganisms through rhizosphere metabolites selectively, which could reduce the reliance on external nutrient acquisition and enhance the stress resilience of C. hystrix. Our study provides a comprehensive perspective for elucidating rhizosphere interaction networks and their ecological functions in C. hystrix, thereby enhancing our understanding of the environmental adaptability of dominant tree species in subtropical forests. Full article

Brown trout (Salmo trutta) populations at the southern edge of the species’ distribution are increasingly exposed to interacting climatic, biotic, genetic, and anthropogenic pressures. This study provides an integrative assessment of the drivers of variation in brown trout density, biomass, and size structure across six Mediterranean river basins in Catalonia (NE Iberian Peninsula), based on long-term standardized electrofishing surveys (2016–2025; 88 sites). Generalized linear mixed models revealed that mean summer temperature, genetic introgression from hatchery-derived Atlantic lineages, and the density of introduced fish species were the most consistent negative predictors of total density, biomass, and juvenile abundance (<120 mm FL). Hydrological and nutrient variables showed comparatively weak or non-significant effects relative to thermal and biotic predictors. Fishing regulations significantly influenced the biomass and density of larger trout (>220 mm FL), with lower values in harvest-allowed sections, whereas total density was less responsive to regulation. These findings indicate that Mediterranean brown trout populations are primarily constrained by thermal conditions, genetic integrity, and biological invasions, with implications for conservation and fishery management under ongoing climate warming. Full article

Soil carbon (C), nitrogen (N), and phosphorus (P) stoichiometry is essential for maintaining fertility and ecosystem functioning, yet its spatial patterns and drivers in large-scale agricultural regions remain unclear. We collected 225 topsoil samples across the Songnen Plain, Northeast China, and used geostatistical methods to map the spatial distributions of soil organic carbon (SOC), total nitrogen (TN), total phosphorus (TP), and their ratios (C:N, C:P, N:P). Feature importance and correlation analyses were employed to assess the relative influence of environmental factors. Results revealed significant spatial heterogeneity, with a consistent north-high, south-low pattern for all elements and ratios. Mean C:N, C:P, and N:P ratios were 11.6, 32.8, and 2.8, respectively. SOC was the dominant controlling factor (importance: 0.5–0.6), showing strong positive correlations with all ratios. Mean annual temperature exerted significant negative effects, while precipitation had limited influence, primarily on C:N. Soil type also mattered, with black soils exhibiting the highest C:N and C:P ratios (11.8 and 36.7). We conclude that soil C:N:P stoichiometry in the Songnen Plain is governed by hierarchical interactions of SOC, climate, and soil type. These findings provide a mechanistic framework for understanding regional nutrient patterns and support the development of spatially targeted management strategies for sustainable soil health. Full article

This review investigates the multifaceted roles of nitrogen-fixing and phosphate-mobilizing bacteria in natural ecosystems, with a particular focus on their contributions to plant growth and sustainable soil management. These microbial communities contribute substantially to nutrient cycling by converting atmospheric nitrogen into plant-available forms and mobilizing insoluble phosphorus in soil, thereby enhancing soil fertility and promoting sustainable plant productivity. This review synthesizes current knowledge on the mechanisms underlying biological nitrogen fixation, phosphate solubilization and mineralization, and the production of plant growth–promoting metabolites. Particular attention is given to plant–microbe interactions and their role in improving nutrient availability, regulating plant physiological processes, and enhancing tolerance to abiotic stresses such as salinity, drought, and heavy metal contamination. The findings underscore the ecological importance of these plant-associated microbial communities and highlight their potential applications in biofertilizer and biostimulant development for sustainable agriculture and reduced dependence on synthetic fertilizers. Full article

Accurately estimating calorie intake and nutrient composition from what we eat remains one of the most practical challenges in maintaining a healthy lifestyle. Manual food logging and database-based estimations are often inaccurate because ingredient proportions and preparation styles vary widely. This paper presents a lightweight, privacy-preserving framework that estimates calories and detailed nutrient values from a single image. The model uses a Mask R-CNN-based segmentation network to identify visible food components, measure their area, estimate their volume using preset height values, and map them to nutritional information obtained from reliable datasets such as USDA and Food-a-pedia. The system integrates federated learning (FL) to ensure privacy by allowing the model to improve collaboratively without sharing raw user data. The proposed architecture achieved a mean Average Precision (mAP) of 96% for detection and 92% for segmentation, confirming its precision and efficiency. The model is trained and evaluated on a curated pizza dataset consisting of 1107 images across 50 topping categories, using a standard train-validation-test split (666/219/222) to ensure reliable performance assessment. The proposed system also achieves low nutrition estimation error, with calorie and nutrient deviations remaining within approximately 3.8% to 11.1% across evaluated metrics. A lightweight mobile interface is demonstrated through a Figma-based prototype mockup to illustrate potential real-world deployment and user interaction. Full article

Dietary phytogenic additives and microalgae are increasingly investigated as natural alternatives to antibiotic growth promoters in rabbit production due to their potential effects on gut health and nutrient utilisation. This study evaluated the nutraceutical potential of Chlorella vulgaris and Laurus nobilis as plant-based additives for growing New Zealand White rabbits. A 45-day feeding trial was conducted using control and experimental diets enriched with 0.1% Chlorella and 0.1% Laurus. Productive performance, nutrient digestibility, blood biochemistry and faecal composition were monitored, and polyphenolic compounds were analysed in feed, blood, faeces and caecal microbiota using HPLC-DAD. Final body weight (3097 vs. 2909 g) and feed intake (142.7 vs. 145.0 g day⁻¹) did not differ significantly between treatments. However, crude protein digestibility was significantly lower in the supplemented group than in the control group (54.39–47.79% vs. 63.73–62.33%; p < 0.05). Faecal chemical composition differed significantly between groups, particularly for dry matter, which was higher in the supplemented group across sampling times. Polyphenols detected across biological matrices confirmed the bioavailability of selected phytochemicals, with ferulic acid showing the highest stability. Correlation analysis indicated shared metabolic or absorptive pathways among several compounds. Overall, low-dose supplementation with C. vulgaris and L. nobilis appears safe and may support improved digestive physiology and nutrient utilisation without compromising rabbit health. Further research with larger sample sizes and detailed microbiome profiling is needed to clarify metabolic interactions and long-term effects of these nutraceutical strategies. Full article