Search Results (177)

The pinewood nematode (PWN, Bursaphelenchus xylophilus (Steiner & Buhrer) Nickle)), first introduced into China in 1982, has since spread rapidly, posing a serious threat to forest resource security and ecological balance. This study aimed to analyze the genetic diversity and genetic structure of PWN in eight geographic populations (60 individuals) of Guizhou Province using single nucleotide polymorphisms (SNPs). Results revealed low genetic diversity (Ho values varied from 0.123 to 0.229; He values ranged between 0.117 and 0.212) across the eight sampled populations, along with low levels of genetic differentiation (pairwise Fst values varied from 0.005 to 0.183) among them. Gene flow was generally high between populations, and no clear geographical clustering was observed based on ADMIXTURE, PCA and phylogenetic analysis. These findings provided a scientific basis for tracking the dispersal and identifying the origins of PWN infestations in China. Full article

Ubiquitins (Ubs) play a crucial role in plant–pathogen interactions, particularly the RPL40 family, which is essential for protein synthesis. While Pinus massoniana is highly susceptible to pine wilt disease (PWD) caused by Bursaphelenchus xylophilus, the defense mechanisms mediated by RPL40s remain poorly understood. Here, we performed a genome-wide identification of the ubiquitin and ubiquitin-like gene family (PmUBQs) in P. massoniana. We identified 30 PmUBQ genes unevenly distributed across 11 chromosomes, which were classified into six subfamilies based on phylogenetic analysis. An analysis of promoter regions indicated that the PmUBQ genes were enriched with cis-acting elements associated with stress responses, hormone regulation, and development. Specifically, two group II members, PmRPL40-1 and PmRPL40-2, located on chromosomes 12 and 11, respectively, were identified and exhibited distinct responses to B. xylophilus infection in resistant and susceptible P. massoniana. PmRPL40-1 was significantly highly expressed in the 15 days post-inoculation, while PmRPL40-2 was downregulated on day 1 and then upregulated. Moreover, both genes showed peak divergence at 15 days post-inoculation; the expression levels of PmRPL40-1 and PmRPL40-2 in resistant P. massoniana were approximately 1.8- and 3.7-fold higher, respectively, than in susceptible P. massoniana. These patterns suggest that PmRPL40s might be involved in the rapid activation of defense responses and late-stage cell repair. Notably, transient overexpression of PmRPL40-1 in P. massoniana led to a significant 1.6-fold increase in the jasmonic acid (JA) content (p < 0.0001). These findings reveal the key PmUBQ genes and suggest that PmRPL40s contribute to PWD resistance potentially through the modulation of JA signaling, offering potential targets for molecular breeding in P. massoniana. Full article

The concept of sustainability has evolved far beyond its initial environmental foundations, expanding into a multidimensional framework that integrates multinational policies, multicultural values, and multigenerational knowledge, but there is a paucity of bottom-up or grassroots research. This paper is a case history comprising oral history supported by rigorous documentation including military records, census data, genealogical records, and scholarship extending over four centuries. A more nuanced understanding of resilience and adaptation emerges. An analysis of recent scholarship indicates that sus-tainability is a dynamic, narrative-driven process that requires an in-depth understanding of the spatial and temporal consequences of global shifts, ranging from climate catastrophes to the global flows of capital and large migrations of people. This paper uses oral history to show the adaptation of a multinational, multicultural, multigenerational family in North America to the social, political, economic, and technological challenges faced over 400 years with a focus on sustainability and resilience. Full article

The present paper investigates the adsorption performance of pinewood-derived biochars produced at two pyrolysis temperatures (850 °C, PW-A; 1000 °C, PW-B), including sieved fractions (PW-A1 and PW-A2) and a functionalized variant (PW-C), for the removal of five short- and intermediate-chain PFASs (PFBA, PFBS, PFHxA, PFHxS, and GenX) from water under continuous-flow conditions. Adsorption behavior was evaluated using Freundlich and Hill isotherm models. The Hill model provided a superior fit for most PFAS–adsorbent systems, highlighting the importance of cooperativity effects, particularly for short-chain PFASs. In single-compound experiments, PFBS and GenX showed the highest adsorption capacities (up to 82.3 and 68.5 mg g⁻¹), while PFBA and PFHxA exhibited the lowest. Among the tested materials, biochar produced at 1000 °C (PW-B) consistently demonstrated the highest adsorption efficiency. Compared to activated carbon, PW-B showed comparable performance for PFBA, PFBS, PFHxA and PFHxS and significantly better performance for GenX. In mixed-PFAS systems, competitive effects reduced adsorption capacity and cooperativity. Sulfonic PFASs showed higher affinity than carboxylic PFASs, following the trend PFHxS > PFBS > PFHxA > PFBA. Overall, the results demonstrate that waste-derived biochar represents a low-cost and sustainable alternative for PFAS removal in realistic water-treatment scenarios, supporting scalable solutions aligned with global environmental goals. Full article

Pine wilt disease (PWD), caused by Bursaphelenchus xylophilus, is a destructive forest disease leading to rapid mortality. Although Chongqing is a major epidemic region in China, the population genetic structure of B. xylophilus and the ecological interactions among nematode occurrence, blue stain formation, and microbial community dynamics remain insufficiently clear. This study systematically surveyed nematode incidence and performed morphological and molecular identification, revealing strong correlations between nematode presence, blue stain, and insect infestation (p < 0.0001). Within Monochamus alternatus, nematodes were mainly distributed in the abdomen and thorax (p < 0.0001). High-throughput sequencing showed significantly higher fungal (e.g., Leptographium) and bacterial (e.g., Burkholderia-Caballeronia-Paraburkholderia) diversity in diseased than healthy pinewood, indicating pronounced microbial shifts during disease progression. mtCOI-based genetic analyses of 162 nematodes from 11 populations revealed five haplotypes, with Hap1 shared across all populations. AMOVA indicated that over 80% of genetic variation occurred within populations, and neutrality and mismatch analyses suggested recent expansion in some populations (Beibei, Jiangbei, Rongchang). These findings clarify nematode epidemiology, microbial shifts, and genetic characteristics in Chongqing, providing a scientific basis for precise sampling, rapid detection, and integrated management of PWD, and suggest that microbial community changes may contribute to rapid pine decline. Full article

Esteya vermicola is a nematophagous fungus with strong parasitic ability against the pinewood nematode (Bursaphelenchus xylophilus) and shows great potential for the biological control of pine wilt disease. However, this fungus is highly sensitive to environmental stress factors and often exhibits early necrosis when cultured on conventional nutrient-rich media, limiting its large-scale application. In this study, we optimized the long-term cultivation and conidiation conditions of E. vermicola CBS115803 by supplementing minimal medium (MM) with amino acids, and evaluated its stress tolerance and infectivity against the pinewood nematode. Among 20 tested amino acids, histidine significantly increased total conidia production, while arginine, glutamine, and proline markedly promoted the formation of lunate conidia. The combination of arginine, histidine, glutamine, and proline (AHGP) produced the highest overall conidia yield and lunate conidia proportion. The MM + AHGP medium maintained long-term colony viability, whereas colonies on PDA and CM media showed obvious degeneration. This formulation also improved mycelial growth, total conidiation, and the proportion of lunate conidia. Moreover, conidia produced on MM + AHGP exhibited the highest germination rates and infectivity under various stress conditions, including cold, heat, oxidative, osmotic, and UV stresses. Conidia germination was significantly enhanced following treatment at 0 °C, suggesting that low temperatures may activate dormancy-breaking pathways. This amino acid-optimized medium offers an effective technical foundation for stable large-scale production and storage of E. vermicola conidia, providing a new avenue for the biocontrol of pine wilt disease. Full article

Pine wilt disease (PWD), caused by Bursaphelenchus xylophilus, is driven by a tri-component system involving the pinewood nematode, Monochamus spp. beetle vectors, and susceptible pine hosts. Chemical control remains a scenario-dependent option for emergency suppression and high-value protection, but its deployment is constrained by strong regional regulatory and practical differences. In Europe (e.g., Portugal and Spain), field chemical control is generally not practiced; post-harvest phytosanitary treatments for wood and wood packaging rely mainly on heat treatment, and among ISPMs only sulfuryl fluoride is listed for wood treatment with limited use. This review focuses on recent progress in PWD chemical control, summarizing advances in nematicide discovery and modes of action, greener formulations and delivery technologies, and evidence-based, scenario-oriented applications (standing-tree protection, vector suppression, and infested-wood/inoculum management). Recent studies highlight accelerated development of target-oriented nematicides acting on key pathways such as neural transmission and mitochondrial energy metabolism, with structure–activity relationship (SAR) efforts enabling lead optimization. Formulation innovations (water-based and low-solvent products, microemulsions and suspensions) improve stability and operational safety, while controlled-release delivery systems (e.g., micro/nanocapsules) enhance penetration and persistence. Application technologies such as trunk injection, aerial/Unmanned aerial vehicle (UAV) operations, and fumigation/treatment approaches further strengthen scenario compatibility and operational efficiency. Future research should prioritize robust target–mechanism evidence, resistance risk management and rotation strategies, greener formulations with smart delivery, and scenario-based exposure and compliance evaluation to support precise, green, and sustainable integrated control together with biological and other sustainable approaches. Full article

The present study investigates the suitability of the invasive herbaceous species Sosnowsky’s hogweed (Heracleum sosnowskyi) and giant knotweed (Fallopia sachalinensis), together with reed (Phragmites australis), as feedstock for pressed biofuel pellets used alone and as additives to pinewood. Biomass of the three herbaceous species and pinewood was harvested, dried, chopped, milled, and pelletized through a 6 mm die to obtain pure pellets and binary mixtures of each herbaceous biomass with pinewood (25, 50, and 75% by weight of herbaceous share). The pellets were characterized for physical and mechanical properties, elemental composition, calorific value, combustion emissions, and life cycle impacts per 1 GJ of heat. Pellet density ranged from 1145.60 to 1227.47 kg m⁻³, comparable to or higher than pinewood, while compressive resistance satisfied solid biofuel quality requirements. The lower calorific values of all herbaceous and mixed pellets varied between 16.29 and 17.78 MJ kg⁻¹, with increased ash and nitrogen contents at higher herbaceous shares. Combustion tests showed substantially higher CO and NO_x emissions for pure invasive and reed pellets than for pinewood, but all values remained within national regulatory limits. Life cycle assessment indicated the highest global warming and fossil fuel depletion potentials for reed systems, followed by Sosnowsky’s hogweed and giant knotweed, with pinewood consistently exhibiting the lowest impacts. Overall, invasive plants and reed are technically suitable as partial pinewood substitutes in pellet production, supporting simultaneous invasive biomass management and renewable heat generation. Full article

Injectable Permeable Reactive Barriers (IPRBs) represent a promising in situ technology for groundwater remediation, with sustainable adsorbents like biochar offering an alternative to activated carbon. This study optimized an IPRB process using a colloidal suspension of pinewood biochar stabilized with sodium carboxymethylcellulose (BC@CMC). The research first characterized the suspension stability under varying hydrochemical conditions, finding optimal colloidal stability at neutral to basic pH (6–9.4), while high ionic strength (>50 mM NaCl) and extreme pH values prompted aggregation. To prevent clogging, a key operational challenge, pre-filtration through a 64-µm sieve was implemented preventing column clogging and facilitating successful deep-bed distribution. The BC concentration was optimized to 3 g L⁻¹, maximizing injectable adsorbent mass. Batch adsorption tests demonstrated the biochar’s high affinity for toluene (TOL) and tetrachloroethylene (PCE), with performance comparable to commercial activated carbon, particularly for PCE. The complete IPRB process was successfully validated through continuous-flow adsorption tests, where columns containing distributed BC@CMC showed high contaminant retention, with experimental retardation factors (R_x) of 144 ± 4 for TOL and 360 ± 6 for PCE. The study confirms that the optimized BC@CMC suspension enables highly efficient IPRB implementation, establishing this approach as a viable and sustainable strategy for field-scale groundwater remediation. Full article

This study presents a sustainable and efficient strategy for removing contaminants of emerging concern (CECs) from wastewater using non-metal-doped pyrochar catalysts synthesized via a green, one-step pyrolytic process from pinewood sawdust, urea, and boric acid. The resulting N- and B-doped pyrochars were evaluated for their ability to activate peroxydisulfate (PDS) and degrade a mixture of 25 CECs (15 pesticides and 10 pharmaceuticals). B-doped pyrochar exhibited superior bifunctional performance, combining high adsorption capacity with efficient catalytic PDS activation. Structural characterization confirmed the incorporation of boron into the carbon matrix, generating electron-deficient Lewis acid sites and enhancing the affinity toward PDS and CECs. Quenching and adsorption–degradation analyses revealed a synergistic combination of radical and non-radical pathways, supported by π–π interactions, hydrogen bonding, and Lewis acid–base interactions. Reusability tests confirmed long-term stability and high degradation efficiency over four cycles. These findings demonstrate the potential of B-doped pyrochar as a cost-effective, stable, and environmentally friendly catalyst for practical wastewater treatment. Full article

Medium-chain aliphatic compounds bearing oxygen-containing functional groups—such as alcohols, ketones, or carboxylic acids—have attracted increasing attention due to their potential as bioactive agents in pest management. These compounds have demonstrated diverse biocidal properties, including insecticidal, antimicrobial, fungicidal, and nematicidal activities. In this study, the nematicidal potency of three structurally related C9 aliphatic ketones—2-nonanone, 3-nonanone, and 5-nonanone—was evaluated against Bursaphelenchus xylophilus, the pinewood nematode (PWN). These isomeric ketones differ in the position of the carbonyl group, providing a useful model for examining structure–activity relationships (SAR) among positional isomers. The direct-contact bioassays, performed at 1 mg/mL, revealed that 2-nonanone exhibited the highest nematicidal activity, causing 92.3 ± 1.2% mortality on the PWN, followed by 3-nonanone at 80.1 ± 0.8%, while 5-nonanone showed significantly lower activity at 17.1 ± 0.5%. The results suggest a strong dependency of bioactivity on the position of the carbonyl group along the carbon chain. The increasing efficacy from 5- to 2-nonanone suggests that proximity of the carbonyl group to the terminal end may enhance activity, for example, by enhancing membrane interaction or disrupting nematode metabolic processes. These findings underscore the importance of molecule structure analysis in designing effective nematicidal agents and support further investigation into terminally positioned oxygenated medium-carbon chain aliphatic compounds as potential leads. This work highlights that subtle structural differences within homologous series can significantly influence bioactivity and provides a foundation for developing targeted, biodegradable nematicides derived from simple aliphatic frameworks. Full article

Animal-derived adhesives have historically played a critical role in East Asian polychrome artworks, yet their influence on coating properties remains insufficiently understood. In this study, three traditional animal glues—bone glue, hide glue, and fish glue—were systematically compared as binding media for cinnabar (red), orpiment (yellow), and lazurite (blue) coatings on pinewood substrates. FTIR spectra of all glues exhibited characteristic collagen-related absorption bands, with bone glue showing a stronger hydroxyl peak at 3280 cm⁻¹. Viscosity analysis revealed bone glue as the most stable, reaching 120 ± 6 mPa·s at 20% concentration, compared with lower values for fish glue and hide glue. Colorimetric analysis indicated that cinnabar coatings were primarily affected by glue concentration, while orpiment coatings showed significant glue-type effects on chroma, with hide glue producing the highest saturation. Lazurite coatings displayed the strongest adhesive-related differences: hide glue enhanced saturation, whereas fish glue increased lightness. Gloss remained consistently low (<3 Gloss Units (GUs)), in line with the matte appearance of historical coatings, although bone glue produced smoother cinnabar surfaces (Ra = 1.72 µm, GU = 3.09). Two-way ANOVA confirmed that both the glue type and concentration significantly influenced chroma, gloss, and roughness. These findings demonstrate that although all animal glues share a collagenous origin, their distinct physicochemical properties shape the optical and microstructural qualities of polychrome coatings, offering a scientific basis for adhesive selection in cultural heritage conservation. Full article

In the current study, lavender plant (Lavandula angustifolia Mill.) waste, as obtained after the essential oils steam distillation process as well as lignocellulose biomass of two of the most common pine species (Pinus nigra L., Pinus brutia L.), was characterized in terms of chemical composition, moisture, ash content, and calorific value, in order of its potential to be used as feedstock material in pellets production to be assessed, studying different materials ratios. The lavender material was introduced at low percentages (0, 5, 10 and 15% w/w) in the feedstock of pellets, in order to maintain the total ash content of the mixed feedstock as adequately low-lying, ensuring the classification of pellets in qualitative categories of A1, A2 and B (residential uses, ENplus). The resultant lavender–pine mixed syntheses were densified in a multi-mold pelletizing machine and the pellets were characterized with regard to physical, morphological, mechanical, hygroscopic, and thermal characteristics, based on the limits set by the respective ENplus standards as benchmarks. The results demonstrated that although lavender waste has a high content of ash and extractives compared to wood, it can be used in a mixture (<15% lavender percentage) with pure wood material to produce pellets of adequate quality for residential use. The lavender waste presence favored pellets’ mechanical strength, dimensions, hydrophobicity, dimensional stability, bulk density (marginally) and resultant quality of the pellets. Lavender slightly decreased the calorific value of pellets, though without recording a significant adverse impact. The lavender material mixed with black pinewood (at 15%) revealed the best pellets’ feedstock performance. The findings exhibited that lavender lignocellulosic residues are suitable for producing high-performance residential pellets, provided that the lavender content does not exceed 15% of the feedstock. Full article

Pine wilt disease (PWD) is an economically important disease. With the increasing temperature caused by climate change, there is a concern that it may expand to regions currently at low risk, cause more serious ecological harm and economic losses in China. The pinewood nematode has an optimal temperature range for development, and historical meteorological conditions, particularly temperature, can influence its current occurrence through time-lagged effects. Lag effect is a temporally delayed effect. In order to investigate the threshold effect and lag effect of temperature on PWD, we collected province-level occurrence data in China and explored the threshold effect, lag effect, and spatial heterogeneity mechanism using a distributed lag non-linear model. The results show that temperature has a significant threshold effect and lag effect on PWD. The threshold temperatures and lag periods vary from 19.5 °C to 25.1 °C and from 1 to 3 months in different provinces in the study area. The threshold temperature shows significant spatial heterogeneity and is positively correlated with the average temperature. This study provides a theoretical basis for the prevention and control of PWD, as well as protection of forest ecological security. Full article

Pine wilt disease, a devastating disease severely impacting pine ecosystems, is caused by the pinewood nematode Bursaphelenchus xylophilus (Steiner & Bührer, 1934) Nickle, 1970 (Nematoda: Parasitaphelenchidae). Controlling B. xylophilus is crucial for preventing and managing pine wilt disease. Recently discovered novel nematocidal lectins could provide more advantageous materials for utilizing genetically engineered bacteria to control this pathogen. Therefore, this study focuses on identifying novel nematocidal toxins within B. xylophilus lectins. Overall, we obtained twenty-one galectin, one L-type lectin (LTL), and three chitin-binding domain (CBD) genes by screening the B. xylophilus genome database; these genes were successfully expressed proteins. The bioassay results indicated that Bxgalectin2, Bxgalectin3, Bxgalectin4, Bxgalectin9, and BxLTL1 induced mortality rates exceeding 50% in B. xylophilus. Notably, Bxgalectin4 showed the strongest nematocidal activity, causing 88% mortality in the treated nematode population. The enzyme-linked immunosorbent assays further demonstrated that Bxgalectin3 (K_d = 8.992 nM) and Bxgalectin4 (K_d = 9.634 nM) had a higher binding affinity to GPI-anchored proteins from B. xylophilus. Additionally, Bxgalectin2 (K_d = 16.50 nM), Bxgalectin9 (K_d = 16.48 nM), and BxLTL1 (K_d = 24.34 nM) can bind to the GPI-anchored protein. This study reports, for the first time, that lectins endogenous to B. xylophilus exhibit nematocidal activity against their own species. These findings open up the possibility of using nematode lectins as potent control agents in the biological control of B. xylophilus. Full article