Search Results (522)

The gut microbiota influences host health, development, nutrition, and behavior, positioning it as a frontier research area in life sciences. Bactrocera dorsalis is a major agricultural pest, with a short life cycle, ease of laboratory rearing, and the availability of germ-free larvae. The gut microbiota of B. dorsalis is complex and relatively insensitive to environmental influences. Due to these advantages, B. dorsalis has emerged as a promising model organism for gut microbiota research. This review synthesizes the advantages of B. dorsalis as a model organism, detailing its gut structure and the composition of its microbiota across developmental stages, sexes, diets, and geographical populations—highlighting the dominance of Enterobacteriaceae as a core component. Key functional roles of gut microbiota in B. dorsalis are elucidated, including nutrient provisioning, regulation of development and reproduction, enhancement of environmental adaptability, behavioral modulation, pesticide resistance, and immune interactions. The mechanisms underpinning gut microbiota homeostasis, involving the host Duox/ROS system, NOX enzymes, and the Imd pathway, are also discussed. Limitations are addressed, alongside future directions for leveraging genetic tools to dissect host–microbe interplay. Furthermore, the potential applications of gut microbiota research—including probiotics for Sterile Insect Technique optimization, microbial-based attractants, and paratransgenesis for pest control—are emphasized. Collectively, B. dorsalis offers a platform for understanding intricate host–microbe interplay and inspires novel pest management strategies. Full article

Inflammatory and immune alterations are increasingly recognized as components of ALS pathology, yet whether they arise as a direct consequence of TDP-43 dysfunction or as a downstream response to neurodegeneration remains unresolved. To address this question, we profiled adult head transcriptomes of Drosophila lacking TBPH, the fly homolog of TDP-43, and identified marked overactivation of the conserved Toll/Imd/NF-κB (Relish) innate immune pathway, including increased expression of antimicrobial effector genes and inflammatory genes. We further found that TDP-43/TBPH regulates the NF-κB homolog Relish by associating with its mRNA and that its loss permits Relish-dependent immune overactivation. Genetic reduction in Relish in TDP-43-deficient flies suppressed inflammatory signaling and ameliorated neurological defects in vivo, indicating that immune dysregulation contributes to TDP-43 loss-associated phenotypes. Full article

Frequent engineering changes in manufacturing require worker instructions to be updated quickly and reliably. In many production environments, however, update handling still depends on manual comparison procedures, delayed communication, or repeated traversal of large document collections, limiting responsiveness during ongoing production changes. This paper presents a hierarchical hash-based method for change detection in structured manufacturing documents as the computational core of a worker assistance system for near-real-time instruction updates in the context of in-line qualification. Heterogeneous instruction data are transformed into canonical hierarchical document structures, from which SHA-512 digests are generated at multiple structural levels. During repeated comparison operations, document-state evaluation is reduced to digest comparison, while structural differences can be localized through hierarchical refinement of affected substructures. The method is integrated into a system architecture that combines predecessor-linked version management with role-specific filtering for controlled dissemination of relevant instruction updates. The approach was implemented in an automotive assembly use case involving structured work instructions and evolving production documentation. The evaluation demonstrates that the proposed approach reduces repeated comparison effort relative to conventional field-wise traversal methods while maintaining the ability to localize structural changes through hierarchical refinement. The reported results focus on computational behavior and implementation feasibility in structured manufacturing environments rather than hardware-specific throughput benchmarks. Overall, the results indicate that hierarchical comparison of structured instruction states provides a practical basis for change-aware worker assistance and controlled propagation of instruction updates in evolving manufacturing environments. The evaluation focuses on repeated-comparison scenarios in structured manufacturing settings and does not address semantic interpretation of detected changes or large-scale distributed deployments. Full article

In many developing regions, the lack of on-site weather data impedes the estimation of rainfall-driven processes, such as soil erosion. Satellite-based precipitation products (SPPs) can support hydrological modelling in gauge-sparse regions by providing continuous rainfall estimates. Accurate rainfall estimation is crucial to soil erosion modelling, particularly in data-scarce regions such as the TRB. In this study, seven satellite-based precipitation products—CHIRPS, IMERG, TRMM, ERA5, GLDAS, and PERSIANN-CDR, along with the IMD gridded dataset—were evaluated for their ability to represent rainfall patterns and support R-factor estimation in the RUSLE framework. This is the first comprehensive evaluation of multiple SPPs for RUSLE-based soil erosion modelling in the Tungabhadra river basin (TRB), providing insights for ungauged watersheds in India. CHIRPS and IMERG displayed relatively smooth and continuous patterns, while PERSIANN-CDR and TRMM exhibited fragmented rainfall zones. ERA5 and GLDAS demonstrated consistent but moderate values across the basin. IMD data served as the reference product for comparison. The findings reveal that the choice of precipitation dataset directly affects the accuracy of erosion estimation. Therefore, multi-dataset evaluation is recommended for reliable assessment of soil loss and watershed planning in ungauged or partially gauged catchments. Full article

Background: Aging is characterized by metabolic dysfunction and neuromuscular decline, and obesogenic diets may exacerbate these processes. High-fat, high-sugar diets (HFHSD) promote adiposity, systemic metabolic dysregulation, and skeletal muscle impairments, yet their impact on motor unit integrity and neuromuscular vulnerability during aging remains unclear. Methods: In a controlled preclinical experiment, late-middle-aged (15-mo-old) female F344 rats were randomized to HFHSD (n = 6) or regular chow (n = 6) for 10 weeks. Longitudinal assessments were conducted at baseline, 6 weeks, and 10 weeks and included body composition, motor unit number estimation (MUNE), forelimb and hindlimb grip strength, gastrocnemius tetanic contractile torque, and post-intervention electrical impedance myography (EIM). Data were analyzed using a two-way mixed-effects ANOVA to assess the effects of diet and time, with statistical significance set at p < 0.05. Results: HFHSD led to significant increases in body mass and adiposity measures (e.g., abdominal circumference, skinfold thickness). Compared with controls, HFHSD rats exhibited significant reductions in hindlimb MUNE (diet effect, p = 0.007) and decreased tetanic contractile torque in both absolute and body mass-normalized values (p ≤ 0.002). Absolute forelimb grip strength increased over time (p = 0.027), though this effect did not persist after normalization to body mass, and hindlimb grip strength did not differ between groups. EIM at 50 kHz revealed elevated resistance in HFHSD rats (p = 0.0497), whereas reactance and phase angle did not differ significantly. Conclusions: This pilot study provides preliminary evidence that an HFHSD, initiated during late middle age, may accelerate neuromuscular decline in female F344 rats prior to the typical onset of age-associated motor unit loss. A 10-week HFHSD intervention was associated with reductions in estimated motor unit numbers, impairments in muscle contractility, and a dissociation between absolute and normalized forelimb grip strength outcomes, indicating a potential early vulnerability of the neuromuscular system to obesogenic dietary exposure. These findings should be interpreted within the context of a modest sample size but collectively support the concept that diet-induced metabolic dysfunction may contribute to early neuromuscular impairment during aging. Full article

Background: Invasive meningococcal disease (IMD) remains a rare but severe condition associated with high mortality and a significant risk of long-term sequelae. Despite global vaccination efforts, the epidemiology of Neisseria meningitidis continues to evolve, with serogroup B (MenB) representing the predominant cause of IMD in many high-income countries. Methods: This consensus document reviews current evidence on MenB epidemiology and the role of the multicomponent meningococcal serogroup B vaccine (4CMenB), with a focus on immunogenicity, strain coverage, real-world effectiveness, and remaining challenges. Results: Protein-based MenB vaccines have overcome the limitations of polysaccharide approaches, demonstrating robust immunogenicity across age groups. Real-world data confirm substantial vaccine effectiveness, particularly in infant immunization programs and outbreak settings, with significant reductions in disease incidence. For example, in England in the 3 years after vaccine introduction, MenB IMD incidence declined by 75% in immunized infants compared to unvaccinated controls. Adjusted vaccine efficacy was 52.7% after the two-dose primary series and 59.1% following the booster dose, highlighting the contribution of the booster. However, protection is influenced by antigenic variability among circulating strains, resulting in incomplete and geographically variable coverage. In addition, antibody waning over time and the limited impact on nasopharyngeal carriage reduce the potential for long-term and indirect protection. These factors highlight the need to optimize vaccination strategies, including the timing of booster doses, particularly in adolescents, and the role of vaccination in different epidemiological contexts. In this regard, it is not precisely defined whether infants who were immunized in the first year of life need a booster dose in the preschool period, especially in countries with a high incidence of MenB disease. Moreover, it is not established whether and when adolescents who were vaccinated both in infancy and during the preschool period need a booster dose. Economic considerations and variability in national immunization policies further contribute to heterogeneity in vaccine implementation. Emerging evidence suggests possible cross-protection against other meningococcal serogroups and Neisseria gonorrhoeae, although findings remain inconsistent across different risk groups and do not allow us to recommend 4CMenB vaccine beyond MenB IBD prevention. Conclusions: 4CMenB is an effective tool for preventing MenB IMD, although further studies are needed. Future strategies should prioritize age-targeted boosting and enhanced genomic surveillance to maximize impact. Full article

Bombyx batryticatus is a traditional Chinese medicinal material derived from Bombyx mori infected by Beauveria bassiana; however, its formation mechanism remains poorly understood. This study compared infection processes in silkworms by two B. bassiana strains with markedly different virulence (highly virulent ZY027 and ARSEF2860). Integrated transcriptomic and proteomic analyses were employed to uncover, for the first time, the molecular basis of B. batryticatus formation at the systems biology level. The results demonstrated significant weight variations in B. batryticatus derived from different fungal strains. ZY027-induced stiff silkworms exhibited higher wet and dry weights than those infected by ARSEF2860. Large-scale gene reprogramming occurred in silkworm hemolymph post-infection, involving marked activation of Toll/Imd immune signaling pathways, ribosome biogenesis, and endoplasmic reticulum stress responses. A notable “uncoupling” between transcriptomic and proteomic profiles was identified, highlighting the critical role of post-translational regulation in host responses. The two strains triggered distinct metabolic reprogramming patterns: ZY027 notably suppressed oxidative phosphorylation and activated detoxification mechanisms, whereas ARSEF2860 presented characteristics of “immune–metabolic optimization.” These findings suggest that B. batryticatus formation involves complex fungus–silkworm molecular interactions in hemolymph, and that fungal strain characteristics are associated with significant differences in host molecular responses and product biomass. The study provides a theoretical foundation and innovative guidance for selecting strains with high B. batryticatus production potential and developing novel entomopathogenic fungal resources. Full article

Honeybee (Apis mellifera) health is governed by the integrated action of detoxification, immunity, and microbiota within complex environmental contexts. The coordinated detoxification system (DETOXome), primarily active in the midgut, fat body, and Malpighian tubules, includes cytochrome P450s, glutathione S transferases, carboxylesterases, and ABC transporters, and functions in concert with innate immune pathways such as Toll, Imd, Jak/STAT, JNK, antimicrobial peptides, and RNA interference. Cellular maintenance mechanisms, including heat shock proteins, proteostasis, and antioxidant defenses, support these systems under chemical, thermal, and pathogen-induced stress. Multi-stressor exposures encompassing pesticides, pathogens, nutritional limitations, and climate variations interact to affect physiological resilience, behavior, and colony function. This review synthesizes molecular, organ-specific, and colony-level evidence to provide a mechanistic framework connecting environmental stressors to detoxification and immune responses. Predictive markers derived from transcriptomic, proteomic, and microbiome analyses offer early detection of sublethal stress, while genomic and selective breeding strategies hold the potential to enhance honeybee resilience. By integrating stress pathways across biological scales, this review advances a unified model of honeybee health that moves beyond descriptive lists to highlight cross-system interactions driving colony survival. Full article

Ethanol is a pervasive chemical stressor in fermentative environments and represents a major ecological challenge for Drosophila melanogaster, a species that naturally inhabits decaying fruits. Although ethanol tolerance has traditionally been attributed to detoxification and antioxidant pathways, accumulating evidence indicates that immune-related genes, particularly those encoding immune deficiency (IMD) pathway-associated antimicrobial peptides (IMD-AMPs), contribute importantly to chemical stress adaptation. Previous studies have demonstrated that IMD-AMP induction is required for ethanol tolerance; however, whether elevated IMD-AMP expression alone is sufficient to enhance tolerance has remained unresolved. In this study, we investigated the functional significance of IMD-AMP upregulation in ethanol tolerance using dietary propolis as an experimental immune-modulating agent. D. melanogaster were reared throughout their life cycle on propolis-supplemented diets and subsequently exposed to ethanol. Propolis-fed flies exhibited significantly enhanced survival under ethanol stress compared with control flies. Notably, this increased tolerance was not accompanied by upregulation of classical ethanol metabolism genes or broad induction of antioxidant-related genes. Instead, propolis feeding increased baseline and early-stage expression of IMD-AMP genes, including Diptericin A (DptA), Diptericin B (DptB), Attacin (AttC), and Metchnikowin (Mtk) before and during ethanol exposure. These findings suggest IMD-AMP upregulation is positively associated with enhanced ethanol tolerance in D. melanogaster. Our results establish a proactive role for immune-related pathways in chemical stress resistance and extend the functional scope of AMPs beyond pathogen defense. This study identifies IMD-AMPs as key effectors linking immune activation to physiological adaptation under ethanol-induced chemical stress. Full article

Insects represent powerful experimental systems for investigating host–microorganism interactions, providing valuable insights into bacterial pathogenicity, immune regulation, symbiosis, and antimicrobial discovery. This review examines the complex relationships between insects and bacteria, focusing on the mechanisms that control infection, immune activation, and microbial adaptation. Particular attention is given to the routes of pathogen entry and to the conserved innate immune pathways that coordinate host defenses, including the Toll, Imd, Duox, and Jak/Stat signaling cascades. The review illustrates how bacterial pathogens exploit toxins, immune evasion strategies, and metabolic adaptation to overcome host defenses, while insects rely on tightly regulated cellular and humoral responses, antimicrobial peptides, melanization, and microbiota-mediated homeostasis. Interactions between pathogenic and commensal bacteria in the insect gut are discussed in the context of immune tolerance, dysbiosis, and ecological adaptation. The dual role of bacterial virulence factors in both pathogenesis and symbiosis is highlighted through examples involving entomopathogenic bacteria such as Photorhabdus spp., Xenorhabdus spp., and Bacillus thuringiensis. In addition, the review summarizes the use of insect models, including Drosophila melanogaster, Galleria mellonella, Bombyx mori, and Apis mellifera, in experimental infections aimed at studying virulence mechanisms, host immune responses, and antimicrobial efficacy. Finally, multi-omic approaches, including transcriptomics, metabolomics, epigenomics, and single-cell technologies are discussed as transformative tools for dissecting host–microbe interactions at molecular and systems levels. Overall, insect–bacteria interactions emerge as dynamic and evolutionarily shaped systems in which immunity, metabolism, microbiota composition, and environmental factors are closely interconnected, offering important perspectives for both basic research and the development of sustainable biocontrol and antimicrobial strategies. Full article

Background/Objectives: Antibiotics are routinely used in crustacean larviculture to mitigate bacterial infections, yet their widespread application compromises larval ontogeny. Probiotics and microalgae offer sustainable alternatives, but their combined molecular effects in crustacean larvae remain poorly characterized. This study aimed to evaluate the physiological and transcriptomic impacts of a probiotics–microalgae consortium versus antibiotics in mud crab (Scylla paramamosain) zoea, with the goal of elucidating mechanisms underlying improved larval development and identifying potential antibiotic alternatives. Methods: Scylla paramamosain larvae were reared under five treatments: clear water control (CN), microalgae alone (MA), probiotics alone (PB), a probiotics–microalgae consortium (PB-MA), and the antibiotic (AB) florfenicol. Samples were collected at 6 h and 24 h post-treatment during the first (Z1) and third (Z3) zoeal stages. Growth performance was assessed via survival and larval stage index, and multi-time point transcriptomic sequencing was performed to analyze dynamic gene expression profiles. Results: The PB-MA consortium significantly enhanced stage-specific survival from Z3 to Z5 and accelerated developmental progression compared to control and antibiotic groups. Transcriptomic analysis revealed from 492 to 2854 differentially expressed genes across treatments. PB-MA treatment was associated with the sustained upregulation of immune-related pathways (lysosome and Toll/Imd signaling), oxidative stress responses (peroxisome and glutathione metabolism), and energy metabolism (TCA cycle and carbon metabolism), whereas antibiotics predominantly suppressed these pathways. Key candidate genes, including NPC1, NAGA, ACOX1, HAO1, MUT, and PK, were prominently induced in PB-MA-treated larvae. Conclusions: The probiotics–microalgae consortium enhances basal immunity, antioxidant capacity, and metabolic adaptability in mud crab larvae at the molecular level. These findings provide transcriptomic evidence supporting the replacement of antibiotics with synergistic microbial consortia in sustainable crustacean larviculture. Full article

Dehydrothyrsiferol (DT), a brominated oxasqualenoid from the red alga Laurencia viridis, represents a compelling example of this framework. This review establishes DT as a model Smart Secondary Metabolite based on the convergence of a unique molecular architecture of rigid stereogroups connected by flexible bonds; a high metabolic yield (0.42% w/w of crude extract); potent selective bioactivity against kinetoplastids and drug-resistant tumors; multi-target modulation of protein phosphatase 2A (PP2A) and cell-surface integrins; and distinctive chemotaxonomic relevance within Macaronesian communities. Its biosynthesis proceeds through stereocontrolled epoxide-opening cascades, generating an evolutionarily refined scaffold. Ecologically, DT operates as a multifunctional shield, providing antifouling protection and deterring herbivory. Pharmacologically, it acts as a selective signaling modulator, triggering integrin-mediated cell death (IMD) in resistant cancer cells and inducing mitochondrial collapse in protozoa. In vivo studies in murine models of cutaneous leishmaniasis have demonstrated an 87% reduction in lesion size, reinforcing its promise as a lead structure. Full article

Pathogen manipulation of host behavior is a widespread evolutionary strategy to enhance its transmission, yet whether different pathogens elicit distinct behavioral and molecular responses in the same host remains poorly understood. We performed parallel behavioral assays and comparative transcriptomic analyses on third-instar Lymantria dispar larvae infected with Lymantria dispar multiple nucleopolyhedrovirus (LdMNPV, virus), Staphylococcus aureus (bacterium) and Metarhizium anisopliae (fungus). Climbing height was recorded over 72 h post-infection, and gene expression pattern was profiled using RNA-seq at 72 h. Only LdMNPV infection induced significant, sustained upward climbing behavior among the three pathogen infection groups. All three pathogens activated Toll and IMD immune pathways, but LdMNPV triggered substantially broader transcriptomic reprogramming. Notably, the virus specifically upregulated multiple energy metabolism pathways (nicotinate/nicotinamide metabolism, pyruvate metabolism, TCA cycle and oxidative phosphorylation) and the neuroactive ligand-receptor interaction pathway—a pattern absent in bacterial and fungal infections. LdMNPV drove tree-top disease through a virus-specific, multi-system manipulation strategy that couples metabolic activation with neural signaling modulation. This comparative study reveals fundamental differences in behavioral manipulation across pathogen kingdoms and provides candidate pathways for functional validation. Full article

A history of invasive mold disease (IMD) often delays or contraindicates allogeneic hematopoietic stem cell transplantation (allo-HSCT) in children. Given the limited data on pediatric patients with pre-allo-HSCT IMD, we aimed to describe the management and clinical outcomes of a cohort of children with IMD prior to allo-HSCT through day +100 post-transplantation. Between 2021 and 2024, ten pediatric patients were identified with proven or probable IMD. Their median age was 8.5 years. The most common pathogens were Aspergillus (n = 5) and Fusarium (n = 4). Infections most frequently involved the lungs followed by paranasal sinuses, bloodstream, liver, and skin. All patients demonstrated clinical improvement before transplantation, and by day +100 post-HSCT, no IMD relapses or infection-related mortality were observed. These findings suggest that complete radiologic or clinical resolution is not a prerequisite for proceeding with transplantation. Recent IMD should not be considered an absolute contraindication to urgent allo-HSCT when clinical improvement is evident, as transplantation facilitates immune reconstitution necessary for definitive infection control. Full article

The single von Willebrand factor C (SVWC) domain-containing protein family represents a crucial class of immune molecules recently identified in insects and crustaceans. Initially regarded as functional analogs of vertebrate interferons (IFNs) due to their virus-induced expression and activation of the Janus kinase-signal transducer and activator of the transcription (JAK-STAT) pathway, recent studies have revealed that SVWC proteins possess far more complex functions. Many SVWC members are themselves a novel class of pattern recognition receptors (PRRs) that can directly bind to viruses and bacteria. Importantly, SVWCs are not a single entity but a highly diverse family—multiple subtypes exist in Drosophila, Bombyx mori, and shrimp—a gene expansion that implies functional differentiation. This review systematically examines the multifunctionality of SVWC proteins in insects and crustaceans, with a particular focus on the functional specialization driven by subtype diversity. We delve into the complex regulatory networks governing SVWC expression, including the differential activation by nuclear factor kappa B (NF-κB) pathways (Dorsal, Rel-2, Relish) and interferon regulatory factor (IRF) pathways. We detail the unique signaling mechanism by which SVWCs activate the JAK-STAT pathway via integrins, rather than the canonical Domeless receptor. Furthermore, we extend the discussion to the emerging roles of SVWCs as PRRs in humoral immunity (activating Toll/IMD pathways to induce antimicrobial peptides) and cellular immunity (mediating hemocyte phagocytosis). Based on current evidence, We propose that diverse SVWC subtypes may recognize distinct pathogens, bind to different integrin receptors, and activate specific STAT variants via disparate upstream induction pathways, thereby establishing a systematic and hierarchical immunoregulatory network. This understanding positions the SVWC protein family as a central hub in the insect immune network and offers a novel perspective on the complexity and evolution of invertebrate immunity. Full article