Occurrence, spatiotemporal dynamics, and ecological risk of fungicides in a reservoir-regulated basin

Insights on common fungicides: A national survey on farmland soils from Mainland China

Fungicides are a growing concern owing to their ecological and human health threats. In China, which is a large fungicide-consuming country, only a few provincial studies have reported several fungicide residues in agricultural soils. Additionally, terrestrial ecological risk assessments of pesticides are limited to the single species. This study showed that fungicides were commonly found in agricultural soils in mainland China, and the Σ13fungicides concentrations ranged from 0.0548 to 3183 μg/kg, with the major contributing component being difenoconazole. Spatial variation in fungicide concentrations was significant, with the highest concentrations observed in Southern China. The Σ13fungicides concentration was higher in soils covered with plastic films compared to uncovered soils, possibly because microplastics from agro-film sources promote fungicide retention in the soil. Among the crop types, the highest fungicide residues were found in soils planted with fruits. In addition, this study was the first to use the probabilistic species sensitivity distribution (pSSD) approach to deduce the predicted no-effect concentrations of major fungicides as terrestrial safety thresholds. Particularly, soil texture conditions may influence the hazard assessment of fungicides. Finally, from the species taxa perspective, the proportions of ecological risks of carbendazim and tebuconazole in agricultural soils in China were 4.3 % and 5.9 %, respectively.

Environmental fates of thiophosphate and triazole fungicides in a paddy-dominated basin

Under the widespread use backgrounds of fungicides in paddy-dominated basin, the neglect of fungicide environmental fates may aggravate their pollution risks. By integrating field detection with model simulation, we quantified the loss loads and explored the environmental fates of one thiophosphate and five triazole fungicides. Based on the experimental results, we simulated fungicide loss loads with the coefficient of determination of the verification results greater than 0.5 (with p-value less than 0.01). The model simulation results revealed that the extensive distribution of paddy fields and the rough terrain in the lower reaches attributed to higher loss loads observed downstream than upstream. Meanwhile, the loss loads in study watershed concentrated from May to October, constituting 92.69 % of the annual total. A robust correlation between fungicide loss and precipitation (with the coefficient of determination greater than or equal to 0.51, p-value less than 0.01) underscores the pivotal role of rainfall in mediating fungicide migration. Transportation has emerged as the primary environmental behavior of fungicides, accounting for at least 92.87 % of the total flux. Furthermore, the results of field investigation showed the application pattern of fungicides also affected the spatial and temporal characteristics of fungicide loss and also the loss load. The combination of experiment and model revealed the migration and distribution patterns of fungicides in the paddy-dominated watershed, facilitating effective management at catchment scale.

Prediction of Potential Risk for Ten Azole and Benzimidazole Fungicides with the Aryl Hydrocarbon Receptor Agonistic Activity to Aquatic Ecosystems

Azole and benzimidazole fungicides are widely used agrochemicals to prevent and treat fungal growth and are frequently detected in aquatic environments. Here, we aimed to assess the aquatic ecological risks of ten currently used azole and benzimidazole fungicides, which with the aryl hydrocarbon receptor (AhR) agonistic activity, and their transformation products (TPs). We obtained over 400 types of aerobic TPs for ten fungicides. Some fungicides and their TPs (approximately 26.7%) exhibited the potential AhR agonistic activity and toxicity to different aquatic species. Meanwhile, some compounds with the chlorine element and benzene ring structure exhibited environmental persistence and mobile ability. Several of them were frequently detected in aquatic environments, posing potential risks to aquatic ecosystems. These harmful fungicides and their TPs should be given attention. This study provides important insight into the aquatic ecological risks caused by azole and benzimidazole fungicides, which can provide theoretical guidance for their pollution control.

Chronic carbendazim exposure disrupts behavioral responses and redox-regulatory mechanisms in non-target detritivore Nauphoeta cinerea nymphs

Carbendazim is widely applied in agriculture to control various fungal diseases during pre-harvest and post-harvest processes owing to its efficacy and cost-effectiveness. However, environmental and food contamination by carbendazim has become a global health issue. Indeed, the declining biodiversity of beneficial insects owing to agricultural intensification is currently of keen concern to the scientific community. The toxicological responses of Nauphoeta cinerea nymphs, a non-target insect, to ecologically realistic concentrations of carbendazim at 0, 0.25, 2.5, 5.0 and 25 μg/L for 50 uninterrupted days were assessed. Neurobehavioral data generated by video-tracking software revealed that chronic nymphal exposure to carbendazim significantly diminished the path efficiency, body rotation, maximum speed, turn angle and distance traveled but increased the immobility time, total time of freezing and episodes of freezing in insects. The deterioration in the locomotor and exploratory abilities of carbendazim-exposed insects was substantiated by high heat map intensity and reduced track plots. Further, chronic carbendazim exposure diminished acetylcholinesterase activity in head of the insects. Chronic carbendazim exposure significantly decreased antioxidant defense mechanisms but increased nitric oxide, hydrogen peroxide and lipid peroxidation levels in fat body, midgut and head of exposed insects. Activities of acid and alkaline phosphatases which play important roles in detoxification and metabolic processes were also markedly decreased in carbendazim-exposed insects when compared with control. Altogether, carbendazim represents an ecological threat to non-target insects through induction of oxido-inflammatory injury, providing valuable insights into the behavioral dysfunction and toxicological mechanisms of carbendazim in beneficial insects.

Demethylation Inhibitor Fungicides Have a Significantly Detrimental Impact on Population Growth and Composition of Nectar Microbial Communities

Demethylation inhibitor (DMI) fungicides are a mainstay of modern agriculture due to their widespread use for crop protection against plant-pathogenic fungi. However, DMI residues can disperse and persist in the environment, potentially affecting non-target fungi. Previous research has demonstrated that DMIs and other fungicides inhibit yeast growth in floral nectar microbial communities and decrease fungal richness and diversity of exposed flowers with no apparent effect on bacteria. Nevertheless, the effect of DMIs on the population growth of different species of nectar inhabitants and the dynamics of these microbial communities remains understudied. To address these issues, in this study we created synthetic microbial communities including yeasts (Metschnikowia reukaufii and Metschnikowia pulcherrima) and bacteria (Rosenbergiella epipactidis and Comamonas sp.) and propagated them in culture media containing different DMIs (imazalil, propiconazole, and prothioconazole) at different doses or no fungicide. Our results showed that DMIs have a significant impact on some of the most common microbial inhabitants of floral nectar by favoring the growth of bacteria over yeasts. Furthermore, habitat generalists such as M. pulcherrima and Comamonas sp. were more impacted by the presence of fungicides than the nectar specialists M. reukaufii and R. epipactidis, especially upon dispersal across habitat patches. Future research should determine if the patterns observed in the present study hold true for other species of nectar microbes and explore the interaction between growth limitation due to fungicide presence, dispersal limitation, and other mechanisms involved in community assembly in floral nectar.

Design and Synthesis of 3-Carene-Derived Amide-Thiourea/Nanochitosan Complexes with Excellent Laccase Inhibitory Activity and Sustained Releasing Performance for Crop Protection

The discovery of natural product-derived novel nanopesticide systems can effectively address the adverse effects caused by the improper use of traditional fungicides. In this research, 33 novel 3-carene-derived amide-thiourea derivatives 5a-5zg were designed using laccase as the biological target, synthesized from natural renewable forest biomass resource 3-carene as the starting material, and structurally confirmed by Fourier-transform infrared spectroscopy, nuclear magnetic resonance, high-resolution mass spectrometry, and single crystal X-ray diffraction. The antifungal activity of the target compounds against eight plant pathogenic fungi was evaluated, and the results presented that target compound 5g exhibited excellent and broad-spectrum antifungal activity against the eight tested phytopathogenic fungi. Furthermore, the important contribution of the gem-dimethylcyclopropane structure in the antifungal activity of compound 5g was revealed through two negative controls without the gem-dimethylcyclopropane structure. Besides, compound 5g also demonstrated a prominent laccase inhibitory activity. The fluorescence quenching of the laccase with compound 5g, the chelating characteristics of compound 5g, and the interaction mode between the laccase and compound 5g presented that the target compound 5g probably exhibited excellent antifungal activity by acting on the laccase target. Cytotoxicity assay revealed that compound 5g had a low cytotoxicity for LO2 and HEK293T cell lines. On the other hand, to further improve the application potential of compound 5g, the 3-carene molecular skeleton containing gem-dimethylcyclopropane ring was grafted onto chitosan, and two nanopesticide carriers CACS and CATCS with sustained releasing performance were synthesized for loading compound 5g. 3-Carene-derived nanochitosan carrier CATCS showed a relatively regular, loose, and porous reticular structure, which displayed high dispersibility and good thermostability. In addition, this carrier had a higher drug-loading capacity and sustained releasing performance than that of the unmodified chitosan. This research identified that the target compound 5g could be used as a promising lead compound for fungicide against the laccase target, meanwhile, the complex 5g/CATCS deserved further study as a nanopesticide candidate.

Spatiotemporal distribution, ecological risk assessment, and human health implications of currently used pesticide (CUP) residues in the surface water of Feni River, Bangladesh

Spatiotemporal monitoring of pesticide residues in river water is urgently needed due to its negative environmental and human health consequences. The present study is to investigate the occurrence of multiclass pesticide residue in the surface water of the Feni River, Bangladesh, using an optimized salting-out assisted liquid-liquid microextraction (SALLME) coupled with liquid chromatography-tandem mass spectrometry (LC-MS/MS). The optimized SALLME method was developed and validated following the SANTE/11312/2021 guidelines. A total of 42 water samples were collected and analyzed to understand the spatiotemporal distribution of azoxystrobin (AZ), buprofezin (BUP), carbofuran (CAR), pymetrozine (PYM), dimethoate (DMT), chlorantraniliprole (CLP), and difenoconazole (DFN). At four spike levels (n = 5) of 20, 40, 200, and 400 μg/L, the recovery percentages were satisfactory, ranging between 71.1 % and 107.0 % (RSD ≤13.8 %). The residues ranged from below the detection level (BDL) to 14.5 μg/L. The most frequently detected pesticide was DMT (100 %), followed by CLP (52.3809-57.1429), CAR (4.7619-14.2867), and PYM (4.7619-9.5238). However, AZ and BUP were below the detection limit in the analyzed samples of both seasons. Most pesticides and the highest concentrations were detected in March 2023, while the lowest concentrations were present in August 2023.Furthermore, ecological risk assessment based on the general-case scenario (RQm) and worst-case scenario (RQex) indicated a high (RQ > 1) risk to aquatic organisms, from the presence of PYM and CLP residue in river water. Human health risk via dietary exposure was estimated using the hazard quotient (HQ). Based on the detected residues, the HQ (<1) value indicated no significant health risk. This report provides the first record of pesticide residue occurrences scenario and their impact on the river environment of Bangladesh.

Antifungal Activity and Mechanism of Camphor Derivatives against Rhizoctonia solani: A Promising Alternative Antifungal Agent for Rice Sheath Blight

Rice sheath blight, caused by the fungus Rhizoctonia solani, poses a significant threat to rice cultivation globally. This study aimed to investigate the potential mechanisms of action of camphor derivatives against R. solani. Compound 4o exhibited superior fungicidal activities in vitro (EC50 = 6.16 mg/L), and in vivo curative effects (77.5%) at 500 mg/L were significantly (P < 0.01) higher than the positive control validamycin·bacillus (66.1%). Additionally, compound 4o exhibited low cytotoxicity and acute oral toxicity for adult worker honeybees of Apis mellifera L. Mechanistically, compound 4o disrupted mycelial morphology and microstructure, increased cell membrane permeability, and inhibited both PDH and SDH enzyme activities. Molecular docking and molecular dynamics analyses indicated a tight interaction of compound 4o with PDH and SDH active sites. In summary, compound 4o exhibited substantial antifungal efficacy against R. solani, serving as a promising lead compound for further optimization of antifungal agents.

Aquatic and sediment ecotoxicity data of difenoconazole and its potential environmental risks in ponds bordering rice paddies

Difenoconazole has a widespread agricultural use to control fungal diseases in crops, including rice. In edge-of-field surface waters the residues of this lipophilic fungicide may be toxic to both pelagic and benthic organisms. To allow an effect assessment we mined the regulatory and open literature for aquatic toxicity data. Since published sediment toxicity data were scarce we conducted 28 d sediment-spiked toxicity test with 8 species of benthic macroinvertebrates. Ecotoxicological threshold levels for effects were assessed by applying the species sensitivity distribution approach. Based on short-term L(E)C50's for aquatic organisms from water-only tests an acute Hazardous Concentration to 5% of the species (HC5) of 100 µg difenoconazole/L was obtained, while the HC5 based on chronic NOEC values was a factor of 104 lower (0.96 µg difenoconazole/L). For benthic macroinvertebrates the chronic HC5, based on 28d-L(E)C10 values, was 0.82 mg difenoconazole/kg dry weight sediment. To allow a risk assessment for water- and sediment-dwelling organisms, exposure concentrations were predicted for the water and sediment compartment of an edge-of-field pond bordering rice paddies treated with difenoconazole using the Chinese Top-Rice modelling approach, the Chinese Nanchang exposure scenario and the Equilibrium Partitioning theory. It appeared that in the vast majority of the 20 climate years simulated, potential risks to aquatic and sediment organisms cannot be excluded. Although the HC5 values based on laboratory toxicity data provide one line of evidence only, our evaluation suggests population- and community-level effects on these organisms due to chronic risks in particular.

Single and joint toxicity of azoxystrobin and cyproconazole to Prochilodus lineatus: Bioconcentration and biochemical responses

Fungicides are widely used across the world to protect crops and their presence in freshwater systems is increasing. However, the evaluation of their potential impacts on non-target organisms is in the minority of studies related to pesticides. In the current research, the single and joint toxicity of azoxystrobin (AZX) and cyproconazole (CYP) was investigated in juvenile fish Prochilodus lineatus. In particular, we evaluated bioconcentration and biochemical responses following a short-term exposure to environmentally relevant concentrations of the fungicides (alone and in mixture). We also determined interactions between the biological responses when the two compounds were used in mixture. Our results demonstrate that AZX and CYP pose a risk to native freshwater fish by causing deleterious effects. Both compounds, alone and in mixture, bioaccumulated in P. lineatus and triggered neurotoxicity and changes in oxidative stress biomarkers in several organs. Moreover, muscle was a target tissue for these fungicides and a synergistic interaction was observed for the mixture. Due to the lack of studies in fish assessing the effects following exposure to AZX-CYP mixtures and considering a realistic exposure situation in agriculture-impacted water bodies, these findings provide new and relevant information for future studies.