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    Legume-cereal intercropping with AMF reduces cadmium bioavailability and enhance land productivity
    Yanan Yang, Weizhen Chen, Zipeng Chen, Huashou Li
    DOI: 10.1016/j.jia.2025.07.017 Online: 15 July 2025
    Abstract2)      PDF in ScienceDirect      

    The combined implementation of intercropping systems and arbuscular mycorrhizal fungi (AMF) inoculation represents a promising phytoremediation strategy for heavy metal-contaminated farmland, providing both ecological and economic benefits. However, additional research is necessary to understand the influence of AMF and intercropping on Cd bioavailability. This study examines the synergistic effects of maize-soybean intercropping and AMF inoculation on crop growth, cadmium (Cd) allocation patterns, and rhizosphere soil dynamics through comprehensive field and pot experiments. Field trials revealed significant yield advantages in maize-soybean intercropping systems, with land equivalent ratios (LERs) of 1.62 (common maize) and 1.64 (sweet maize). Intercropping decreased soybean Cd accumulation across all tissues, notably in grains (42.8% reduction), while maintaining maize grain Cd concentrations below China's food safety threshold (0.20 mg kg-1). The metal removal equivalent ratio (MRER) achieved 1.33-1.38 in field conditions, validating intercropping's dual advantage in productivity and Cd phytoextraction. Pot experiments indicated the AMF-inoculated intercropping system (IN+A) increased maize yield by 16.4% while reducing Cd accumulation in both crops, with grain concentrations meeting safety standards. Rhizosphere analysis demonstrated IN+A treatment substantially improved soil health indicators: 34.5% reduction in bioavailable Cd, elevated pH, decreased redox potential (Eh), and enhanced catalase activity. AMF colonization rates were 2.2-4.3 times higher in inoculated treatments (11.5-14.0%) versus controls (3.2-5.3%). These results establish that AMF-enhanced legume-cereal intercropping reduces Cd bioavailability through soil alkalinization (pH increase) coupled with redox potential reduction, and metal allocation plasticity redirecting Cd to root tissues. This interaction between microbial symbiosis and plant community design stabilizes Cd in soils while maintaining crop safety (grain Cd<0.20 mg kg-1), establishing an ecoengineering approach for contaminated farmland remediation.

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    Canopy microenvironment and hormonal coordination meditate defoliation dynamics under altered sink-source in high-density cotton
    Zhenwang Zhang, Kexin Li, Keke Yu, Mingfeng Yang, Yukun Wang, Qinghua Liao, Jiaqi Zhang, Xuelian Tang, Guodong Chen, Sumei Wan, Shanwei Lou, Fangjun Li, Xiaoli Tian, Zhaohu Li, Mingwei Du
    DOI: 10.1016/j.jia.2025.07.016 Online: 15 July 2025
    Abstract3)      PDF in ScienceDirect      

    The sink-source balance critically regulates leaf abscission dynamics in cotton (Gossypium hirsutum L.), yet its targeted manipulation to optimize defoliation efficiency remains unexplored.  Here, we conducted a two-year field experiment with cultivars ‘Xinluzao 78’ (XLZ78) and ‘Yuanmian 11’ (YM11) under four sink-source treatments: no cutting source and sink treatment (CK), cutting 1/2 leaves per plant (1/2L), cutting 1/2 bolls per plant (1/2B) and cutting all bolls per plant.  Concurrently, XLZ78 received differential irrigation regimes (deficit: 2970 m³ ha-¹; conventional: 3,420 m³ ha-¹; supplementary: 4,095 m³ ha-¹) to probe boll retention effects.  Key findings revealed that sink reduction (1/2B, 0B) delayed defoliation by elevating leaf relative water content (LRWC) and phytohormones (IAA and ZR), while suppressing ABA, and canopy temperature, compared to CK.  This ultimately reduces the activity of cellulase (CEL) and polygalacturonase (PG) in the abscission zone.  Specifically, 1/2B and 0B reduced defoliation rates by 7.3 and 13.4% (XLZ78) and 0.8 and 9.2% (YM11), over the two-year average.  The 1/2L treatment had a similar effect to the cutting boll treatment. Conversely, supplementary irrigation (I4095) enhanced boll retention, sink-source ratios and canopy temperature during the defoliant application period, which increased the leaf abscission rate by 14.0% over deficit irrigation (I2970).  Mechanistically, under sink limitation conditions, the combination of lower canopy temperature and hormonal changes suppresses the activation of abscission zones.  These results demonstrate that managing sink-source equilibrium by minimizing leaf damage while optimizing boll load fine-tunes defoliation efficiency through microenvironment-hormone crosstalk.  Our work advances the physiological framework for precision defoliation strategies in high-density cotton systems, reconciling mechanical harvesting efficiency with yield preservation.

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    Biodegradable mulch films support root proliferation and yield in water-saving rice production
    Haihe Gao, Changrong Yan, Joann K. Whalen, Wenqing He, Hongjin Liu, Jixiao Cui, Daozhi Gong, Karen Mancl, Qin Liu, Xurong Mei
    DOI: 10.1016/j.jia.2025.07.015 Online: 15 July 2025
    Abstract2)      PDF in ScienceDirect      

    Water-saving rice systems must maintain yield targets while reducing water consumption. Applying biodegradable film to cover the soil surface reduces water loss through evapotranspiration, establishing a warmer, more humid microenvironment for rice growth compared to traditional paddy rice systems. This study examined soil water regimes for rice production in northeast China, comparing rice growth with and without biodegradable mulch film under continuous flooding, drip irrigation, and controlled irrigation conditions. The implementation of biodegradable mulch film elevated soil temperature and sustained soil moisture during early rice development. Continuous flooding with biodegradable mulch film yielded the highest rice production (9.4 Mg ha-1) and net profit of approximately 11,800 CNY ha-1. Drip irrigation with biodegradable mulch film achieved maximum water efficiency, demonstrating the highest water productivity (1.25 kg m-3) and minimum water consumption (235 mm). Root length, weight, and surface area in the 0-40 cm soil layer exhibited positive correlations with water productivity, shoot dry matter, and yield, indicating that root morphological characteristics, particularly during the panicle initiation stage, enhanced rice production and water conservation. The findings demonstrate that biodegradable mulch film created favorable soil conditions for root proliferation, enabling higher yields in water-saving rice systems.

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    Monitoring agricultural arthropod diversity by eDNA metabarcoding from plant cleaning fluid
    Xiaoxiao Song, Cong Dang, Ran Li, Fang Wang, Hongwei Yao, David W. Stanley, Gongyin Ye
    DOI: 10.1016/j.jia.2025.07.014 Online: 15 July 2025
    Abstract2)      PDF in ScienceDirect      

    Arthropods serve essential roles in crop production as pollinators, predators, and pests. Understanding arthropod biodiversity is crucial for assessing agroecosystem health, functions, and services. Traditional survey methods are labor-intensive, costly, and rely on diminishing taxonomic expertise, limiting their agricultural applications. Environmental DNA (eDNA) metabarcoding of diverse samples provides comprehensive species composition data through efficient and non-invasive sampling. However, this method remains underutilized in rice field studies. This research examined four sample substrates - RPCF, rice pollen, soil, and water - using various barcoding primers to identify optimal substrates for monitoring rice paddy arthropod diversity. The method was implemented in Bt- (Bacillus thuringiensis Berliner) rice and non-Bt rice fields to evaluate its biomonitoring potential. Results indicate that the COI primer (mlCOIintF/jgHCO2198R) identified the highest number of rice field arthropod species. The eDNA collected from RPCF detected 15% more arthropod species compared to vacuum sampling of whole arthropods. Rice pollen collection during the heading stage also revealed considerable arthropod diversity. Alpha diversity and taxonomic composition remained consistent between Bt- and non-Bt rice fields, aligning with traditional survey findings. These results suggest that eDNA metabarcoding of plant cleaning fluid offers an effective approach for monitoring agricultural arthropod communities, contributing to agricultural production optimization.

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    Deep storage irrigation can recharge farmland deep soil moisture and sustain production of summer maize (Zea mays L.) through flood resources utilization in irrigation districts of northern China
    Xiaodong Fan, Xiaotao Hu, Yakun Wang, Dianyu Chen, Wene Wang, Fang Wang, Qing Zha
    DOI: 10.1016/j.jia.2025.07.013 Online: 15 July 2025
    Abstract2)      PDF in ScienceDirect      

    The irrigation districts of Northern China face issues such as water scarcity, inability to effectively utilize flood resources, and groundwater overexploitation. In view of these challenges, this study proposes a new concept of deep storage irrigation through flood resources utilization. However, whether deep storage irrigation can recharge deep soil moisture and sustain crop production still requires further study. A two-year field experiment was conducted on summer maize in the Guanzhong Plain with five soil wetting layer depths (T1: 60 cm; T2: 90 cm; T3: 120 cm; T4: 150 cm; T5: 180 cm) and soil saturation moisture content as the irrigation upper limit. The results presented that the ranges of deep soil moisture recharge in the 100–200 cm soil profile (SMS100–200) was 73.34267.42 and 0–150.03 mm in 2021 (wet season) and 2022 (normal season). When the effective precipitation and irrigation exceeded 390 mm, the SMS100–200 began to linearly increase. The highest grain yield (GY) were observed at T2 and T3 treatments in 2021 (11.44 t ha−1) and 2022 (11.25 t ha−1), respectively. The maize GY of T4 in 2021 and T5 in 2022 were only 3.9 and 5.7% lower than the maximize GY, respectively. However, the SMS100–200 for T4 and T5 were 2.4 and 5.0 times that of T2 and T3 treatments in 2021 and 2022, respectively. Overall, the further increase in irrigation amounts induced only a slight decrease in grain yield, but it significantly increased deep soil moisture recharge. Therefore, the deep storage irrigation breaks through the traditional idea of water-saving irrigation with limited water resources, which can be utilized as an effective alternative to address the issues of water scarcity, low flood resources utilization, and groundwater level declines in the irrigation districts of northern China.

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    Underlying mechanisms of high carbon budget surplus in low-stubble rice ratooning in Southeast China
    Qiaohong Fan, Jingnan Zou, Zhimin Lin, Gui Chen, Wu You, Kai Su, Wenxiong Lin
    DOI: 10.1016/j.jia.2025.07.012 Online: 08 July 2025
    Abstract8)      PDF in ScienceDirect      

    The rice ratooning (RR) pattern is increasingly gaining attention in southern China due to its low carbon emissions and high yield characteristics.  However, the net carbon budget balance and the underlying mechanisms remain unknown.  Three rice planting patterns were established in this trial experiment conducted from 2021 to 2022 in Fuzhou (25°17′N, 119°18′E), Southeast China: the ratooning rice pattern (MC+RSR) for rice ratooning, single-cropping rice (LR1), and double-cropping rice (ER+LR2).  The closed static dark box gas collection, dry matter determination, Life Cycle Assessment (LCA) etc. approaches were utilized to investigate the mechanism of "high carbon fixation - low emissions" in the rice ratooning system.  This was achieved through a comprehensive evaluation across multiple dimensions, including crop yield, GHG emissions, carbon and nitrogen footprints, resource utilization efficiency, carbon fixation capacity, and carbon budget balance.  The results showed that the average daily yield of the ratooning season rice (RSR) across different RR patterns from 2021 to 2022 was 28.21 to 47.40% higher than that of the main crop (MC) and single-cropping rice (LR1), and 13.50 to 27.76% higher than that of the double cropping system. This discrepancy was attributed to a 3.32-6.85% increase in the allocation of 13C photosynthetic products (including NSC) to panicle organs and a 21.77-43.51% reduction in allocation to underground roots and soil of RSR.  Moreover, the average daily GWP values are 16.44 kg CO2-eq ha⁻1 for ratoon rice (MC+RSR), 24.99 kg CO2-eq ha⁻1 for single-cropping rice (LR1), and 21.32 kg CO2-eq ha⁻1 for double-cropping rice (ER+LR2).  Specifically, the average daily GWP of ratoon rice is 34.21% lower than that of single-cropping rice and 22.90% lower than that of double-cropping rice.  Similarly, the average daily GHGI of ratoon rice is 62.28% lower than that of single-cropping rice and 28.96% lower than that of double-cropping rice.  In terms of carbon and nitrogen footprints, the ratoon rice model exhibited average daily values of 34.54 kg CO2-eq ha-1 and 22.72 kg N-eq ha-1, respectively.  In comparison, the single-cropping rice model had average daily values of 45.63 kg CO2-eq ha-1 and 24.49 kg N-eq ha-1, while the double-cropping rice model showed averages of 43.38 kg CO2-eq ha-1 and 24.77 kg N-eq ha-1, indicating the reductions of 24.30 and 7.23% in carbon and nitrogen footprints compared to the single-cropping rice model, as well as reductions of 20.38 and 8.30% relative to the double-cropping rice system.  Furthermore, the average carbon budget surplus across the three cropping systems is as follows: 22,380.01 kg CO2-eq ha-1 for ratoon rice (MC+RSR), 11,228.54 kg CO2-eq ha-1 for single-cropping rice (LR1), and 23,772.15 kg CO2-eq ha-1 for double-cropping rice (ER+LR2).  Therefore, the resource utilization efficiency of the ratoon rice model (MC+RSR) was 23.92 and 47.50% higher than that of the single-cropping rice model (LR1) and the double-cropping rice model (ER+LR2), respectively.  Furthermore, the average daily economic benefits increased by 32.71 and 80.75%, respectively.  These findings provide a robust theoretical foundation and practical guidance for advancing agricultural carbon neutrality technologies and ensuring food security.

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    Gene mapping of a mutant mungbean (Vigna radiata L.) reveals that a gene encoding a MYB transcription factor regulates the male sterility trait
    Qian Wang, Jingbin Chen, Shanshan Zhu, Yaming He, Xingxing Yuan, Yun Lin, Ranran Wu, Jinyang Liu, Qiang Yan, Na Yuan, Xin Chen
    DOI: 10.1016/j.jia.2025.07.011 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Mungbean (Vigna radiata L. (Wilczek)) is an important food legume crop.  The utilization of heterosis based on male sterile lines can help increase mungbean yields, yet genetic studies on mungbean male sterility are rare.  Therefore, it is of great significance to explore the male sterility genes in mungbean.  In this study, a no-pollen male sterile mutant vrnpms (Vigna radiata no pollen male sterility) was identified in mungbean.  Gene mapping was conducted using F2 populations derived from the cross between vrnpms and V2709.  The gene controlling the male sterility was mapped to a 426.65 kb region on chromosome 6.  A candidate gene VrMYB80 (EVM0016947), encoding a protein homologous to MYB80 transcription factors, exhibits a 52-kb deletion in vrnpms, resulting in a truncated protein lacking the C’-terminus.  A molecular marker linked to the male sterility phenotype was developed based on the deletion in vrnpms.  Functional complementation in Arabidopsis demonstrated that VrMYB80 could restore fertility in the myb80 mutant.  Subcellular localization showed that VrMYB80 was located in the nucleus. Transcriptional activation assays revealed that the C’-terminus of VrMYB80 was the transcriptional activation domain.  The result of in-situ hybridization indicated that VrMYB80 is expressed in the anther tapetum.  The expression level of downstream VrMS1 was down regulated in vrnpms, indicating that Vrmyb80 with the truncated C’-terminal transcriptional activation domain failed to activate downstream genes, which was the reason of sterility of vrnpms.  The findings of this study contribute to unraveling the molecular genetic mechanism underlying pollen development in legume crops and pave the way for utilizing heterosis in mungbean.

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    Decade-long fertilization and Bradyrhizobium inoculation reconfigure soybean rhizosphere microecology through fungal community assembly and metabolic niche partitioning
    Wanling Wei, Mingchao Ma, Xin Jiang, Fangang Meng, Ping He, Jun Li
    DOI: 10.1016/j.jia.2025.07.010 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Soil microbial-metabolite interactions influence crop productivity, yet their responses to long-term nutrient management in legume systems warrant further investigation. This study examined how fertilization and Rhizobium inoculation reshape soybean rhizosphere fungal-metabolite networks to improve soil health. Through a decade-long field trial utilizing Internal Transcribed Spacer (ITS) sequencing and Liquid Chromatography-Mass Spectrometry (LC-MS) metabolomics, four treatments were evaluated: control (CK), phosphorus-potassium fertilization (PK), PK with nitrogen fertilization (PK+N), and PK with Bradyrhizobiumjaponicum 5821 inoculation (PK+R). Results indicated that nitrogen fertilization increased fungal diversity at maturity and enhanced co-occurrence network complexity (displaying the highest node and edge counts), while Bradyrhizobium inoculation promoted stochastic assembly. Soil fungi exhibited notable correlations with 3-Hydroxymethylantipyrine, Chrysophanol, 3,7-Dihydroxyflavone and Triethylamine. Metabolite profiling revealed nitrogen suppression of stress-resistance flavonoids (3-Hydroxymethylantipyrine, Chrysophanol, 3,7-Dihydroxyflavone), whereas Bradyrhizobium enhanced these key metabolites. KEGG enrichment identified tryptophan and caffeine metabolism as central during flowering-podding, coordinating nitrogen assimilation and defense responses. Additionally, the key metabolites correlated significantly with soil total nitrogen, organic matter, and available nitrogen. These findings reveal that Bradyrhizobium acts synergistically with fertilization to activate fungal-driven metabolic pathways, offering a microbiome-based approach to enhance nitrogen efficiency and reduce agrochemical dependency in soybean systems.

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    Novel AP-SNPs mitigate cadmium stress by regulating carbon-nitrogen metabolism and antioxidant defense system in rice
    Zaid Khan, Songpo Duan, Fan Xianting, Sajjad Ahmad, Chuan Jin, Chunmei Yang, Mohammad Nauman Khan, Kangkang Zhang, Hong Shen
    DOI: 10.1016/j.jia.2025.07.009 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Selenium (Se) is known for alleviating cadmium (Cd) toxicity in rice (Oryza sativa L.), but algal polysaccharides-selenium nanoparticles (AP-SNPs) mitigating Cd stress by regulating carbon-nitrogen metabolism is unknown.  Herein, we found that AP-SNPs improved root and leaf cell ultrastructure, leaf stomatal and photosynthetic traits and reduced the Cd translocation from roots to shoots via Se absorption, translocation as well as upregulating the transcription factors of Se encoding genes OsPT2, OsNIP 2;1, and OsSULTR1;2 at 7 and 14 days after treatment (DAT).  The findings showed that AP-SNPs promoted the concentrations of metabolites and enzymes of carbon-nitrogen metabolism by upregulating the transcript levels of OsRbcS2, OsCS1, OsAGPL1, OsAMT1, OsNRT2.1, OsNR2, OsGS1, and OsGOGAT1 genes.  Additionally, AP-SNPs addition increased the levels of SOD by 11-13%, POD by 10-8%, and CAT by 8-12%, respectively, at 7 and 14 DAT to counteract the damage of reactive oxygen species (ROS) under Cd stress.  The results revealed that AP-SNPs promoted the carbon and nitrogen metabolism, physiological status, and antioxidant defense system of rice and decreased the Cd content in rice root by 12-23%, rice shoot 30-39%, total Cd content 28-46%, and Cd translocation factor 14-27%, respectively at 7 and 14 DAT.  The significant correlation matrixes of the partial least square model (PLSM) and Mantel test further quantify the above findings and imply that AP-SNPs can be a green and sustainable biological compound that regulates carbon-nitrogen metabolism and the antioxidant defense system of rice to minimize Cd transfer from roots to shoots and the food web.

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    Biochar's superior surface properties over straw contribute to soil N losses reduction and crop yield improvement
    Debo He, Dongni Hu, Jinbo Zhang, Zhixin Dong, Bo Zhu
    DOI: 10.1016/j.jia.2025.07.008 Online: 08 July 2025
    Abstract4)      PDF in ScienceDirect      

    Excessive nitrogen (N) losses from cropland are serious threats to sustainable agricultural and ecological development.  Recently, straw and biochar (BC) have been widely applied in cropland to reduce soil N losses, but the mechanisms by which their physicochemical properties affect soil N cycling and soil N losses remain unclear.  This study investigated the responses of soil N transformation and crop yield on BC and straw applications through incubation and field experiments.  Density function theory (DFT) calculations were performed to determine the different impacts of straw and BC on soil N losses at the molecular scale.  Our results indicated that BC application at a weight percent of 3 (3.0wt %) exhibited superior performance in promoting soil N transformation.  The superior physicochemical properties of BC over straw contributed to enhanced interaction and adsorption energies with NO3--N and NH4+-N, which reduced soil N losses by 20.2% from interflow of field experiment compared to straw.  BC application reduced soil N2O by 45.0% compared to the field with conventional fertilization by modulating the functional genes of microorganisms and weakening the soil denitrification.  Although BC increased soil NH3 volatilization by improving urease functional genes (ureC, UreB) compared to straw, it also significantly improved N use efficiency in 25.3% of the crops compared to straw.  Thus, in calcareous purple soils, 3.0 wt% BC content provided superior performance in terms of enhanced N cycling, reduced N losses and improved crop yields compared to straw.  In conclusion, these findings provide insights into optimizing cropland BC application and enhancing soil fertility for sustainable agricultural and ecological developments.

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    Reconstructed organic rice fields: Effects on soil organic carbon, total nitrogen, their mineralization, and rice yield in Japanese Andosols
    Valensi Kautsar, Takamori Kanno, Kaho Sakai, Riza Kurnia Sabri, Keitaro Tawaraya, Kazunobu Toriyama, Kazuhiko Kobayashi, Weiguo Cheng
    DOI: 10.1016/j.jia.2025.07.007 Online: 08 July 2025
    Abstract3)      PDF in ScienceDirect      

    To examine the impact of anthropogenic land reconstruction, particularly the consolidation of small terraces into larger fields, on soil organic carbon (SOC), total nitrogen (TN) dynamics, rice yield, and its components, soil and plant samples were collected from seven newly reconstructed fields in Japanese Andosols in Tochigi, Japan. Samples were obtained from both the former low- and high-elevation sides within each field plot. During harvest season, nine rice plants were randomly selected from each plot (0.675 m2, comprising 3 rows and 3 hills per row), collected from a 3-meter stretch along both the east (former low side) and west (former high side) ridges. Soil cores were collected from identical plots at two depths (0–15 and 15–30 cm) and combined into one composite sample per layer. Rice plant samples were air-dried for two weeks until reaching constant moisture content, after which stems and ears were separated and weighed to determine biomass, yield, yield components, and nitrogen uptake. The indicated that land reconstruction significantly affected rice yield and its components between the two sides of all field plots. SOC, TN, and their decomposition following land reconstruction showed notable changes, especially in the 15–30 cm subsurface soil layer. Additionally, grain weight demonstrated significant correlation with SOC, TN, and carbon decomposition in both the 0–15 cm and 15–30 cm layers, indicating that soil fertility to a depth of 30 cm was crucial for rice productivity after land reconstruction.

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    Rational nitrogen application improves photosynthetic capacity and yield by prolonging the leaf source function of drip-irrigated rice
    Zhiwen Song, Guodong Wang, Lei Zhao, Qingyun Tang, Xinjiang Zhang, Qifeng Wu, Yuxiang Li
    DOI: 10.1016/j.jia.2025.07.006 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Nitrogen (N) not only provides nutritional support for grain development but also lays the foundation for efficient photosynthesis and yield formation by regulating leaf function and delaying senescence.  However, the regulation of leaf function during the reproductive growth stage and its relationship with yield under drip irrigation remain unclear.  Therefore, from 2020–2021, a cultivar with high nitrogen use efficiency (high-NUE) (T-43) and a low-NUE cultivar (LX-3) were used as the study materials and were grown under drip irrigation with four N fertilization levels (0, 150, 300, and 450 kg ha−1); the differences in leaf morphology, photosynthetic characteristics, hormone contents, antioxidant enzyme activities, biomass (mass), and yield were analysed.  The results revealed the following: (1) N application significantly increased the yield of drip-irrigated rice (17.38-74.03%), and with increasing N application rate, the leaf area index (LAI), chlorophyll a+b (Chl a+b) content, maximum net photosynthetic rate (Pnmax) and mass initially increased but then decreased, reaching optimum values under N300, whereas the flag leaf area (LA) continued to increase.  (2) Between the cultivars, T-43 presented relatively high LA and N-metabolizing enzyme activities, thereby increasing the Chl a+b content, light saturation point (Isat), and mass accumulation; LX-3 presented relatively high abscisic acid (ABA) content, and the accelerated degradation of Chl b resulted in an increased Chl a/b ratio, which inhibited Pnmax.  (3) Structural equation modelling (SEM) further revealed that indole-3-acetic acid (IAA) directly increased Pnmax to increase photosynthetic efficiency, whereas the positive promoting effect of IAA and N-metabolizing enzymes on Chl a+b indirectly increased the LAI and N agronomic efficiency (NAE), thus promoting the positive effects of LAI (0.477***) and Pnmax (0.715***) on yield.  In summary, under the appropriate N application rate (300 kg ha−1), in the high-NUE cultivar (T-43), the leaf functional period was maintained, and the photosynthetic capacity was increased via increased hormone contents and antioxidant enzyme activities.  The results of this study provide a theoretical basis for the efficient production of drip-irrigated rice in arid areas.

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    Productivity and economic benefits of winter wheat in Northwest China by optimizing irrigation and planting density
    Muhammad Fraz Ali, Liijuan Ma, Irsa Ejaz, Wanrui Han, Shengnan Wang, Xiang Lin, Dong Wang#Muhammad Fraz Ali, Liijuan Ma, Irsa Ejaz, Wanrui Han, Shengnan Wang, Xiang Lin, Dong Wang
    DOI: 10.1016/j.jia.2025.07.005 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Winter wheat is a key staple crop in Northwest China, yet optimizing its productivity and economic returns remains a challenge due to water constraints and suboptimal planting densities.  This study evaluates the combined effects of irrigation strategies and planting density (PD) on winter wheat yield, resource-use efficiency, and net economic benefits (NEB).  A two-year field experiments were conducted under four irrigation treatments (I1, no irrigation; I2, before winter and jointing; I3, jointing; I4, jointing and anthesis) and three PD treatments (PD1, 562.5×104 plants ha-1; PD2, 375 ×104 plants ha-1; PD3, 187.5×104 plants ha-1).  Through field trials, we identified optimal water-saving irrigation regimes and planting densities that maximize grain yield while enhancing water productivity. Our results demonstrated that lower PD (187.5×10⁴ plants ha⁻¹) under reduced irrigation significantly improved dry matter accumulation (DMA), SPAD, and leaf area index (LAI), leading to higher grain yield.  Moderate irrigation at the jointing stage (I3) enhanced grain yield in higher planting densities by up to 18.42% compared to other irrigation regimes, while the highest overall yield (6,310 kg ha⁻¹) was achieved in medium PD under I3 irrigation.  Water-use efficiency (WUE) was significantly improved by reducing irrigation at specific growth stages, mitigating excessive evapotranspiration.  The PD3-I3 achieved the highest NEB, exceeding I1, I2, and I4 by 11.9, 18.4, and 16.4% in 2022-23, and by 15.1, 14.0, and 8.4% in 2023-24, respectively.  The findings provide practical insights for sustainable wheat production, ensuring higher profitability while conserving water resources.  Implementing optimized irrigation and PD strategies offers a strategic pathway to improving food security and farm income in the semi-arid regions of Northwest China.

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    qMrdd3, a major QTL conferring durable resistance to maize rough dwarf disease
    Qingkang Wang, Weixiao Zhang, Suining Deng, Fei Ni, Wei Xu, Qingzhi Liu, Yuqiang Diao, Yongzhong Zhang, Mingliang Xu, Baoshen Liu
    DOI: 10.1016/j.jia.2025.07.004 Online: 08 July 2025
    Abstract6)      PDF in ScienceDirect      

    Maize rough dwarf disease (MRDD), caused by Fijivirus, poses a significant threat to global maize production.  Using a recombinant inbred line (RIL) population derived from the resistant parent CML199 and the susceptible parent Zheng58, we identified three MRDD resistance QTLs on chromosomes 2, 6, and 9, accounting for 12.71, 5.89, and 11.04% of the total phenotypic variation, respectively.  Among them, the major locus qMrdd3 on chromosome 2 demonstrated incomplete dominance, conferring a resistance enhancement of 26.36–34.47% across diverse environments.  Fine-mapping refined qMrdd3 to a 227.7-kb interval containing five candidate genes, among which Zm00001d002441 was specifically upregulated in the resistant near-isogenic line (NIL-R) following RBSDV infection.  Additionally, two co-segregating markers were developed to facilitate efficient marker-assisted selection.  Introgression of qMrdd3 into Zheng58 and Chang7-2 enhanced field resistance by 38.84 and 26.47%, respectively.  This study provides a valuable genetic resource for MRDD resistance breeding through QTL dissection, elite germplasm development, and marker-assisted breeding.

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    Effects of sulfur fertilizer on the bread-making quality of wheat depend on the nitrogen input level
    Xiu Zhang, Bin Zeng, Donghai Ding, Wei Zhou, Xinglong Dai, Mingrong He
    DOI: 10.1016/j.jia.2025.07.003 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    The bread-making quality of wheat is significantly influenced by both sulfur (S) and nitrogen (N) fertilizers when soil S deficiency occurs.  However, it is not clear whether the end-use quality of bread wheat can be improved by the application of S fertilizer in the absence of soil S deficiency.  In this study, two bread wheat cultivars, Gaoyou 5766 and Zhouyuan 9369, were subjected to three N rates (100, 200, and 300 kg N ha-1) and two S rates (0 and 67.5 kg S ha-1).  The effects of the N and S fertilizers on the grain N and S concentrations, grain N/S ratio, grain protein concentration (GPC), grain protein composition, glutenin polymerization degree, and quality traits were investigated.  The results showed that the responses of the two cultivars to the application of S fertilizer in the GPC, the grain N/S ratio, and the ratio of high molecular weight glutenin subunit to low molecular weight glutenin subunit were similar under each N input level.  However, the effects of S fertilizer on the ratio of glutenin to gliadin (Glu/Gli ratio), the glutenin polymerization degree, the dough rheological properties, and the bread-making quality varied with the N input level in the absence of soil S deficiency.  At the N rate of 100 kg N ha-1 without S input, the grain N/S ratios were below 12.2:1; application of S fertilizer resulted in a decreased Glu/Gli ratio and glutenin polymerization degree, lower dough strength, and decreased end-use quality.  At the N rate of 200 kg N ha-1 without S input, the grain N/S ratios were in the range 13.7:1–15.9:1, and application of S led to an increased Glu/Gli ratio and glutenin polymerization degree.  As a result, the dough strength increased but the dough extensibility decreased, the end-use quality was maintained.  At the N rate of 300 kg N ha-1 without S input, the grain N/S ratios were higher than 15.9:1, and application of S resulted in an increased Glu/Gli ratio and glutenin polymerization degree, thereby increasing the dough strength and end-use quality.  As shown by correlation analysis, the bread-making quality of wheat was closely associated with the Glu/Gli ratio and the polymerization degree of glutenin as modified by N and S fertilizers.  In conclusion, the combination of N and S exerted effects on wheat bread-making quality by changing the relative abundance of specific S-rich and S-poor proteins.  When there is no S deficiency in the soil, application of S fertilizer favors improvement in the bread-making quality of wheat only when the N/S ratio in grains is close to, or higher than, 16:1.

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    PxGalectin-4 with single carbohydrate recognition domain involved in the immunity of Plutella xylostella against entomopathogenic fungus Isaria cicadae
    Yongli Zhou, Ying Lu, Yue Xing, Jian Liang, Xiangli Dang
    DOI: 10.1016/j.jia.2025.07.002 Online: 08 July 2025
    Abstract7)      PDF in ScienceDirect      

    The diamondback moth, Plutella xylostella represents a worldwide threat to Brassicaceae crops and has developed substantial resistance to conventional insecticides. Entomopathogenic fungi (EPF) have emerged as environmentally sustainable alternatives to chemical insecticides. Since insect immunity constitutes the primary defense against fungal pathogens, understanding these mechanisms could advance biocontrol strategies. Nevertheless, research on the immune functions of galectins in insects remains limited. This study identifies a Galectin-4 homolog in P. xylostella (PxGalectin-4) and systematically examines its immunological functions against an EPF Isaria cicadae infection. The open reading frame of PxGalectin-4 encoded 338 amino acids with a carbohydrate recognition domain (CRD). PxGalectin-4 expression exhibited peak levels in late-instar larval stages and fat body, and increased significantly following I. cicadae challenge. Functional characterization demonstrated that recombinant PxGalectin-4 (rPxGalectin-4) directly bound cells and cell wall components of microbes, and displayed Ca2+-dependent microbial agglutination. Additionally, rPxGalectin-4 enhanced hemocyte-mediated immune responses by promoting nodulation and encapsulation, and increased phenoloxidase activity of hemolymph. Knockdown of PxGalectin-4 significantly increased the susceptibility of P. xylostella larvae to I. cicadae infection. In conclusion, PxGalectin-4 serves a vital immune function in P. xylostella defense against I.cicadae, and presents a potential target for novel pest control strategies.

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    The homeodomain transcription factor VvOCP3 negatively regulates white rot resistance in grape
    Zhen Zhang, Cui Chen, Changyue Jiang, Hong Lin, Yuhui Zhao, Yinshan Guo
    DOI: 10.1016/j.jia.2025.07.001 Online: 08 July 2025
    Abstract5)      PDF in ScienceDirect      

    Grape white rot is a fungal disease caused by Coniella diplodiella (Speg.) Sacc. (C. diplodiella) that seriously affects fruit quality and yield; however, the underlying mechanism governing the plant response to C. diplodiella pathogens is still poorly understood. Here, we characterized a homeodomain (HD) transcription factor from grape (Vitis vinifera), VvOCP3, and demonstrated its significance in C. diplodiella resistance. Expression analysis showed that VvOCP3 expression was significantly down-regulated upon inoculation with C. diplodiella. Functional analysis with transient injection in grape berries and stable overexpression in grape calli demonstrated that VvOCP3 negatively regulates grape resistance to C. diplodiella. Further studies showed that VvOCP3 directly binds to the promoter of VvPR1 (pathogenesis-related protein 1) and inhibits its expression, resulting in reduced resistance to C. diplodiella. In addition, VvOCP3 can interact with the type 2C protein phosphatase VvABI1, which is a negative modulator of the ABA signaling pathway. In summary, our findings suggest that VvOCP3 plays a crucial role in regulating white rot resistance in grape, and offer theoretical guidance for developing grape cultivars with enhanced C. diplodiella resistance by regulating the expression of VvOCP3.

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    Multi-trait genome-wide association studies reveal forage yield-related candidate genes and favorable haplotypes in hulled oats (Avena sativa)
    Jin Li, Xu Zhao, Jingbo Yu, Qingping Zhou, Shiyong Chen
    DOI: 10.1016/j.jia.2025.06.025 Online: 25 June 2025
    Abstract12)      PDF in ScienceDirect      

    Hulled oat is an important cereal crop for both animal feed and human consumption, as climate change accelerates and the world's population grows, improving oat breeding is crucial to ensure a stable food supply. Genome-wide association studies (GWAS) are instrumental in pinpointing single nucleotide polymorphisms (SNPs) associated with phenotypic variations within germplasm collections. This study assessed six crucial agronomic traits (plant height, stem length, spike length, flag leaf length, flag leaf width, and stem diameter) across five environments in 266 globally sourced hulled oat varieties, employing 34,896 SNPs for a comprehensive genetic analysis via restricted two-stage multi-locus multi-allele (RTM)- and Bayesian-information and linkage-disequilibrium iteratively nested keyway (Blink)-GWAS methodologies. Our analysis identified 54 SNP linkage disequilibrium blocks (SNPLDBs), and 52 SNPs associated with the six agronomic traits. A total of 105 quantitative trait loci (QTLs) were identified within a ±2 Mb physical region surrounding these loci. Of these, 14 stable QTLs were consistently detected across multiple environments and by both GWAS methods. Haplotype analysis within these QTL regions identified three to five haplotype alleles, each significantly influencing the phenotypic variation of traits across different environments. Combining gene annotation, literature review, and transcriptome data, we identified 35 candidate genes involved in signal transduction, transcriptional regulation, metabolism, and cell development. These findings provide valuable genetic resources for enhancing agronomic traits and yield in oat breeding programs under diverse environmental conditions.

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    Comparative transcriptomic analysis of Chinese cabbage's defense responses to Alternaria brassicae
    Qi Zeng, Qingguo Sun, Xinru Hou, Lin Chen, Ruixing Zhang, Xue Bai, Xifan Liu, Xiaowu Wang, Lugang Zhang, Baohua Li
    DOI: 10.1016/j.jia.2025.06.024 Online: 25 June 2025
    Abstract6)      PDF in ScienceDirect      

    Black spot is a fungus disease elicited by Alternaria brassicae infection and causes devastating damage to Chinese cabbage. We explored the molecular mechanisms of Chinese cabbage’s defense responses to A. brassicae infection by comparative transcriptomic analysis. Notably, we found that the expression of BrERF109 was induced by A. brassicae infection. Silencing of BrERF109 by an optimized VIGS assay in Chinese cabbage reduced disease resistance, whereas BrERF109-overexpression in Arabidopsis enhanced disease resistance. Furthermore, silencing of BrERF109 in Chinese cabbage repressed the expression of indolic glucosinolates genes thus significantly lowered the indolic glucosinolates levels, while BrERF109-overexpression in Arabidopsis induced indolic glucosinolates accumulation. BrERF109 could directly bind the promoter of BrIGMT4, thereby promoting the indolic glucosinolates accumulation and actively defending against A. brassicae. Our study uncovered the BrERF109-BrIGMT4 regulatory module in Chinese cabbage’s defense responses to A. brassicae infection, as well as providing valuable dataset to further explore plants-A. brassicae interactions.

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    AcMYB12 and AcMYB29 promote onion (Allium cepa L.) flavonols biosynthesis through transcriptional regulation
    Qingwei Jia, Shuting Gai, Yiren Wang, Zhihui Zhang, Xiong Wu, Wenhui Wu, Yumeng Pang, Xiaonan Zhang, Lei Qin, Yong Wang
    DOI: 10.1016/j.jia.2025.06.023 Online: 25 June 2025
    Abstract33)      PDF in ScienceDirect      

    Flavonols have high medical value and are crucial for plant stress resistance. They are also key components of the nutritional value in onions, particularly in the edible parts. Although the flavonol biosynthetic pathway is well studied, its regulation in onions is not fully understood. This study screened flavonol biosynthesis and regulatory genes by analyzing transcriptome and metabolomics data from different developmental stages of “SA1.” Two R2R3-MYB transcription factors, AcMYB12 and AcMYB29, were identified as positive regulators of onion flavonol biosynthesis. Transcriptional activation assays showed that both could activate AcCHS, AcF3’H, and AcFLS. Yeast one-hybrid assays confirmed they directly bind to the promoters of these genes. Flavonol pathway genes expression and flavonol content in overexpressed onion callus and Arabidopsis were significantly higher than in controls, supporting the role of AcMYB29 and AcMYB12 in flavonol regulation. Instantaneous silencing tests revealed partial functional redundancy between the two. Interestingly, There were also significant differences in their ability to regulate. AcMYB12 mainly regulates flavonol accumulation, whereas AcMYB29 focuses on quercetin. We further investigated the molecular mechanisms of differential regulation, likely due to variations in cis-elements in flavonol pathway gene promoters and differences in binding activity between transcription factors and cis-elements.

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