Search Results (170)

Tripartite interaction among arbuscular mycorrhizal fungi (AMF), small grain cereals—including wheat, barley, oats, and rye—and pathogenic organisms constitute a highly complex ecological system with major implications for plant health, productivity and resilience. AMF colonization increases nutrient acquisition, particularly phosphorus and nitrogen, while concurrently priming host defense mechanisms that increase resistance to a broad spectrum of pathogens. These benefits, however, are strongly context-dependent and modulated by AMF species composition, host genotype, soil characteristics, and environmental conditions. AMF activate resistance pathways and modulate the rhizosphere microbiome, underscoring their central role in shaping plant–pathogen dynamics. Importantly, the relevance of these interactions extend beyond crop protection and yield stability to encompass food security and sustainability goals aligned with the One Health framework, which recognizes the interconnectedness of plant, environmental, and human health. Field implementation of AMF-based strategies has the potential to reduce reliance on chemical fertilizers and pesticides, thereby promoting sustainable cereal production, restoring soil biodiversity, and enhancing ecosystem services, with downstream benefits for human nutrition and environmental safety. This review integrates current knowledge on AMF–cereal–pathogen interactions, synthesizing mechanistic advances and applied perspectives while identifying critical knowledge gaps that must be addressed to effectively deploy AMF in resilient and sustainable agroecosystems within a One Health context. Full article

Drought and soil nutrient deficiency are critical constraints on plant growth and ecological restoration in desert steppes; however, the interactive mechanisms between arbuscular mycorrhizal fungi (AMF) and phosphorus fertilization remain poorly elucidated. To investigate the regulatory mechanisms governing root system architecture (RSA) remodeling and regrowth capability in Agropyron under drought stress, a controlled experiment was conducted using two genotypes: Inner Mongolia (NM) and Xinjiang (XJ). The experimental design comprised three water regimes (70%, 50%, and 30% field capacity [FC]), two P levels (P0, P1), and two inoculation treatments (A0, A1). The results indicated the following: (1) Although drought significantly inhibited Agropyron growth, the combined application of AMF and P (A1P1) induced a highly significant synergistic effect, augmenting total aboveground biomass by 66.08–160.58% compared to the control. This synergy exhibited distinct “environmental dependency,” being most pronounced under moderate drought conditions (50% FC). (2) Mechanistic analysis revealed that A1P1 optimized RSA by significantly increasing total root length, root surface area, and root volume (e.g., total root length increased by 281.4–375.1% under severe stress), thereby enhancing water and nutrient acquisition. (3) The A1P1 treatment significantly mitigated the decline in regrowth potential induced by successive clipping, sustaining a higher tiller number (increasing by up to 1.8-fold in the 3rd clipping). (4) The XJ genotype was characterized by higher basal biomass and root investment “high-yield phenotype”, whereas the NM genotype demonstrated greater sensitivity to AMF-P regulation “highly responsive phenotype”. In conclusion, the synergistic interaction between AMF and P mitigates drought stress by reshaping RSA and enhancing regrowth capability, providing a theoretical basis for the efficient management of arid grasslands. Full article

Plant domestication studies have traditionally focused on morphological factors that are under direct selection, e.g., fruit size, overlooking the consequences of domestication on ecosystem services. We addressed this knowledge gap by documenting for first time the soil carbon (C) sequestration potential in wild relatives and domesticated cultivars of breadfruit (Artocarpus), a long-lived tree crop. We evaluated aggregate-bound and bulk organic C pools in breadfruit wild relatives and domesticates in soils that varied in nitrogen (N) and phosphorus (P) fertility with management practices (fertilizer and mulch). We determined whether C levels were linked to plant domestication, abiotic factors (N, P, pH, and texture), or biotic factors with known links to C accrual (arbuscular mycorrhizal fungi (AMF), and microbial biomass). In low N or N: P soils, increasing breadfruit domestication was associated with reductions in macroaggregate C (by 50%) and bulk C (host determinism); these shifts were associated with AMF hyphal productivity (50% lower than in wild relatives), soil N and P, and microbial biomass. With a high soil N fertility, the levels of aggregate and bulk soil C were similar between wild relatives and domesticates (plasticity). Despite the limited number of cultivars sampled (n = 10) and the different management practices among sites, our findings suggest domestication effects on ecosystem services, especially those modulated by AMF and soil N fertility. The calculated soil C stocks averaged 99.5 Mg C/ha (range 70–122 Mg C/ha), supporting the possibility of C accrual in breadfruit agroforestry. Full article

Sustainable care of urban lawns requires methods that maintain high turf quality while reducing the use of chemical fertilizers. The objective of this three-year field study was to evaluate whether microbial inoculants can complement or partially substitute conventional fertilization (65–190 kg N·ha⁻¹, 33–35.2 kg P·ha⁻¹, and 124.5 kg K·ha⁻¹) required to maintain high turf quality in an intensively managed lawn system. The experiment was conducted in Poland on a degraded chernozem, classified as Haplic Phaeozem. A standard mixture of perennial ryegrass and fescue was evaluated under four treatments: (1) untreated control; three commercial microbial formulations: (2) StymGrass P+K, containing nutrient-solubilizing Bacillus spp.; (3) BioVitaGrass, combining Bacillus spp. with arbuscular mycorrhizal fungi (AMF); and (4) NitroGrass, containing nitrogen-fixing Azotobacter spp. with Bacillus spp. All microbial treatments improved lawn quality compared with the untreated control. Lawns receiving BioVitaGrass or NitroGrass showed the strongest responses, including denser plant cover, greener and finer leaves, reduced disease symptoms, and increased concentrations of nutrients in the plant tissue. StymGrass P+K produced smaller but still positive effects. Measurements of plant conditions, such as leaf greenness and canopy development, also indicated improved photosynthetic activity in inoculated plots. These results support the role of plant growth-promoting bacteria (PGPB) and arbuscular mycorrhizal fungi in nutrient mobilization, root stimulation, and stress resilience. Although most evidence comes from crops, this study provides novel field-based confirmation of multi-functional microbial inoculant efficacy in turfgrass under this study’s conditions. Full article

Excessive fertilizer use drives soil degradation and resource waste. This study investigates how arbuscular mycorrhizal fungi (AMF) formulations (powder vs. granular) optimize maize (Zea mays L.) yield, soil microbiome, and economic benefits under 50% and 75% fertilizer reduction. Field trials showed that the AMF powder formulation under 50% fertilizer reduction (AP50) increased maize yield by 14.67%. This increase was associated with rapid root colonization (85.3%), enhanced phosphorus availability, and the recruitment of beneficial fungi such as Mortierellomycota. Granular formulation at 75% reduction (AG75) achieved 7.18% yield gain via sustained symbiosis. Fungal communities exhibited greater sensitivity to fertilization than bacteria (Chao1, p = 0.0094), with AMF suppressing Fusarium by 42% while enriching functional taxa (Actinobacteria, Mortierellomycota). Economic analysis confirms that AP50 (30,435 CNY/ha) and AG75 (26,954 CNY/ha) yield higher net profits, where CNY denotes Chinese Yuan. Powder formulations maximize immediate benefits in medium- to low-fertility soils, whereas granules support long-term soil health in high-organic systems, providing a precision strategy for sustainable agriculture. Full article

For future Mars colonization, crop production will be a challenge due to the chemical composition of the Martian Regolith, which contains perchlorates and heavy metals. This research was conducted to determine if the use of Arbuscular Mycorrhizal Fungi (AMF), Plant Growth-Promoting Bacteria (PGPB), and fertilization have a positive effect on tomato growth in a Martian Regolith Analog. The analog contains 52.54% SiO₂, 1.81% TiO₂, 17.66% Al₂O₃, 9.46% Fe₂O₃, 0.145% MnO, 3.43% MgO, 7.09% CaO, 3.95% Na₂O, 1.96% K₂O, and 0.55% P₂O₅. Two hundred and forty tomato plants were grown for 45 days. One hundred and twenty tomato plants grown over perchlorate-polluted analog (1% m/m) died in less than 2 weeks, while 120 tomato plants grown in a non-polluted analog survived. Forty-eight plants supplemented with Long–Ashton solution increased their shoot length 100% more than the control plants and the plants inoculated with the commercial AMF formulation TM-73^MR and PBB; the latter showed 25% mycorrhizal colonization. There was no significant difference between the growth parameters of inoculated plants and non-inoculated plants. However, there was a significant difference compared to the plants supplemented with Long–Ashton solution. The perchlorate is toxic to tomato plants, and the metal content of the analog was not a limiting factor for tomato growth or AMF colonization. Full article

This systematic review critically evaluates and synthesizes current evidence on the efficacy of biostimulants in enhancing soybean seed yield and quality. A comprehensive literature search was conducted following the PRISMA approach using the Web of Science (WoS) database, focusing on peer-reviewed studies from 2014 to 2025 reporting on the effects of biostimulants applied alone or in combination with other agro-inputs on soybean performance. Over 500 publications were retrieved from the database, of which 72 were included in this review. Extracted data were used to calculate changes in yield (kg ha⁻¹), percentage yield increase (%), oil content (%), and protein concentration (%). Our synthesis demonstrated that the sole application of biostimulants, including seaweed extracts, humic acids, amino acids, and beneficial microbes (Bradyrhizobium, PGPR, AMF), consistently enhanced soybean yield by 4% to 65%, while their interaction with other agro-inputs was shown to be capable of increasing yield by more than 150% under abiotic stress conditions, indicating strong synergistic effects. These improvements are mediated through various physiological mechanisms such as enhanced nutrient uptake, improved root growth, increased photosynthetic efficiency, and elevated stress tolerance. Furthermore, biostimulant application positively affects seed quality, increasing oil and protein content by 0.4–5.5% and 0.5–7.3%, respectively, by optimizing source–sink relationships and metabolic pathways. Overall, the greatest benefits are frequently observed through synergistic combinations of biostimulants with one another or with reduced rates of mineral fertilizers, highlighting a promising pathway toward sustainable crop intensification in soybean systems. Full article

This study evaluated the efficiency of arbuscular mycorrhizal fungi (AMF) in promoting the growth, yield, protein, and phytochemical contents of Glycine max cv. Morkhor 60. A completely randomized pot experiment was conducted for 90 days in non-sterile soil with nine replications. Three AMF species were tested and compared with two non-mycorrhizal controls, with and without NPK fertilizer. All AMF treatments enhanced plant growth, photosynthetic rate, and water-use efficiency compared with the unfertilized control. Inoculation with Acaulospora dilatata KKU-SK202 produced the highest pod number and increased 100-seed weight by 27.00% and 4.13% over the non-inoculated and NPK treatments, respectively. Gigaspora margarita KKU-SK210 yielded the highest total protein and phenolic contents, while A. dilatata KKU-SK401 showed the highest antioxidant activity (72.09%). Metabarcoding analysis revealed that AMF inoculation reduced root colonization by pathogenic fungi, with G. margarita KKU-SK210 and A. dilatata KKU-SK202 being the most effective. These results suggest that AMF inoculation can enhance soybean productivity and seed quality while reducing chemical fertilizer dependency and pathogenic fungal incidence. Full article

Agroecology is increasingly shaped by the convergence of traditional knowledge, farmers’ lived experiences, and scientific research, fostering a plural dialog that embraces the ecological and socio-political complexity of agricultural systems. Within this framework, soil biodiversity is essential for maintaining ecosystem functions, with soil microbiology, and particularly arbuscular mycorrhizal fungi (AMF), playing a pivotal role in enhancing soil fertility, plant health, and agroecosystem resilience. This review explores the synergy between agroecological practices and AMF by examining their ecological, economic, epistemic, and territorial contributions to sustainable agriculture. Drawing on recent scientific findings and Latin American case studies, it highlights how practices such as reduced tillage, crop diversification, and organic matter inputs foster diverse and functional AMF communities and differentially affect their composition and ecological roles. Beyond their biological efficacy, AMF are framed as relational and socio-ecological agents—integral to networks that connect soil regeneration, food quality, local autonomy, and multi-species care. By bridging ecological science with political ecology and justice in science-based knowledge, this review offers a transdisciplinary lens on AMF and proposes pathways for agroecological transitions rooted in biodiversity, cognitive justice, and territorial sustainability. Full article

Restrictions on crop production in Ultisols are primarily driven by low soil fertility, which leads to the unsustainable use of soil resources and food insecurity. Significantly, arbuscular mycorrhizal fungi (AMF) enhance nutrient availability for plants, which in turn contributes to greater soil productivity and supports sustainable crop production. This study aims to evaluate the effects of AMF inoculation combined with chemical fertilisation on maize growth and yield in three series of Ultisols. A pot experiment was performed with a 2 × 3 factorial CRD with five replications. Two factors were studied as follows: (1) AMF (Glomus sp.) (non-AMF and AMF inoculation) and (2) rates of chemical fertiliser (0, 50, and 100% of the recommended fertiliser rate for maize, CF). The results showed that AMF significantly enhanced the growth and yield of maize at all CF rates for all soil series at p ≤ 0.01. Total biomass and grain yield following AMF treatment were markedly higher than yields obtained without treatment. Likewise, AMF significantly improved the photosynthetic physiology and NPK content of maize. The CF rate had a negative impact on AMF root colonisation, and AMF efficiency also decreased as the CF rate increased. The relative mycorrhizal dependency (RMD) on maize growth and yield was the highest at 0% CF, with averages of 34.49% and 52.35%; however, these values decreased to 7.43% and 8.73% at 100% CF, respectively. Despite this, the RMD of maize growth and yield remained positive for all soil series. These findings suggest that AMF are an effective means of supporting sustainable maize cultivation in Ultisols. Full article

Limited phosphorus (P) availability and declining soil biological health are major constraints in intensive rice (Oryza sativa L.)—wheat (Triticum aestivum L.) systems. Rock phosphate–enriched compost (REC), combined with microbial inoculants, offers a sustainable strategy for improving soil biological functioning. A field experiment was conducted under a randomized block design with seven treatments involving different combinations of REC, chemical fertilizers, phosphate-solubilizing bacteria (PSB), and arbuscular mycorrhizal fungi (AMF). Post-harvest soil samples from rice and wheat were analyzed for microbial biomass carbon (MBC), microbial biomass phosphorus (MBP), enzymatic activities, microbial populations, root colonization, yield, and P uptake. The combined application of REC with PSB and AMF significantly enhanced soil biological parameters compared with recommended fertilizer doses. Under the REC + PSB + AMF treatment, dehydrogenase, acid phosphatase, and alkaline phosphatase activities increased by 77.4%, 24.8%, and 18.1%, respectively, while MBC and MBP improved by 51.6% and 106.6%. Bacteria, fungi, and actinomycete population increased by 55.0%, 76.7%, and 82.8%, respectively, as well as mycorrhizal root colonization increased by 18.7%. Grain yield of rice and wheat increased by 16% and 6%, respectively, along with higher P uptake. The integrated use of REC with PSB and AMF improved soil enzymatic activity, microbial biomass, and nutrient acquisition, leading to higher crop productivity. These results indicate that REC combined with PSB and AMF is an effective nutrient management strategy for improving soil biological health, P utilization, and crop productivity in rice–wheat systems. Full article

Rhizosphere microbiota, serving as pivotal drivers of multifunctionality in grassland ecosystems, are jointly shaped by the dual influences of biotic and abiotic factors. Among biotic components, plant functional types selectively modulate microbial communities through root exudate specificity, while soil fauna (e.g., nematodes and earthworms) drive microbial interaction networks via biophysical disturbances and trophic cascades. However, excessive nematode grazing suppresses the hyphal extension of arbuscular mycorrhizal fungi (AMF). Moderate grazing facilitates the proliferation of ammonia-oxidizing bacteria through fecal input, whereas intensive grazing induces topsoil compaction, leading to a dramatic 40–60% reduction in lipopolysaccharide content in Gram-negative bacteria. Long-term chemical fertilization significantly decreases the fungal-to-bacterial ratio, while organic amendments enhance microbial carbon use efficiency by activating extracellular enzymatic activities. Regarding abiotic factors, the stoichiometric characteristics of soil carbon, nitrogen, and phosphorus directly regulate microbial metabolic strategies. Hydrological dynamics influence microbial respiratory pathways through oxygen partial pressure shifts—drought stress inhibits mycelial network development. Future research should focus on predicting the emissions of gases such as N₂O (ozone monomer) and optimizing nitrogen fertilizer management to significantly reduce greenhouse gas emissions at the source. The soil organic carbon storage in grassland ecosystems is extremely large. Effective prediction and management can make these soils become important carbon “sinks”, offsetting the carbon dioxide in the atmosphere. At the same time, transcriptomics and metabolic flux analysis should be combined with multi-omics technologies and in situ labeling methods to provide theoretical basis and technical support for developing mechanism-based and predictable grassland restoration and adaptive management strategies from both macroscopic and microscopic perspectives. Full article

Arbuscular mycorrhizal fungi (AMF) form symbiotic relationships with most crops. They function as promising sustainable agricultural amendments by synergizing with biochar to enhance plant nutrient uptake. However, the effects of AMF and biochar interactions on the yield and nutrient uptake of leguminous crops and the underlying mechanisms remain insufficiently understood. This study employed a two-factor experimental design. Under the baseline conditions of no fertilization (CK), chemical fertilizer application (CF), and biochar-based fertilizer application (BF), treatments with and without AMF inoculation were established, resulting in a total of six experimental treatments. Compared to BF treatment alone, the combined application of AMF and BF (AM + BF) synergistically increased soybean biomass (12.81%) and grain yield (19.45%). This synergistic effect was accompanied by increased plant nitrogen (14.04%) and potassium (21.82%) accumulation. Notably, despite the highest yield, the AM + BF treatment showed a 22.22% reduction in nodule formation rate. This reveals that plant nitrogen acquisition strategies have shifted from relying on biological nitrogen fixation to efficient mycorrhizal pathways, reflecting an inherent optimization of carbon economy. The PLS-SEM model revealed that AMF inoculation altered yield-driving mechanisms: in the absence of AMF, yield could be directly predicted by soil nutrient levels; however, this relationship was disrupted after AMF inoculation. The soil nutrient pathway became non-significant, indicating a transition from a soil chemistry-dependent model to a biologically driven one, where AMF–plant symbiosis became the primary regulator of nutrient uptake. These findings highlight that AMF-BF synergy creates a novel soil–plant feedback mechanism that enhances nutrient acquisition efficiency and optimizes carbon allocation, providing a sustainable approach to boost legume crop yields and reduce environmental footprints. Full article

Cactus pear (Opuntia ficus-indica (L.) Mill.) is increasingly recognized as a climate-resilient crop in arid and semi-arid regions, yet its performance is often constrained by poor soil fertility and limited external inputs. Arbuscular mycorrhizal fungi (AMF) are known to enhance phosphorus uptake, water relations, and stress tolerance in many species, but their contribution to cactus pear growth remains largely unexplored. One-year-old cladodes were grown in pots filled with sandy loam soil, either inoculated with a mixed AMF consortium or kept as non-inoculated controls. Plant growth was assessed after 6 and 12 months by measuring cladode number and surface area, shoot and root dry weight, and biomass allocation indices. Inoculated plants produced more cladodes, developed a larger canopy surface area, and accumulated greater root and shoot biomass than controls. These gains reflected an overall acceleration of growth, while biomass partitioning (root-to-shoot balance) remained stable. AMF inoculation substantially enhanced the vegetative growth of O. ficus-indica, pointing to its promise as a sustainable practice for improving cactus pear cultivation in nutrient-poor and water-limited soils. Full article

A field study was conducted on the plants of two grapevine cultivars, ‘Solaris’ and ‘Regent’, grafted onto an SO 4 rootstock (V. berlandieri × V. riparia) and characterized by strong growth and yield. The effect of twelve treatments on the concentration of macroelements in leaf blades in the véraison phase, as well as selected soil parameters, was assessed in the sixth, seventh and eighth year of their application. The following treatments were tested: control (no fertilization), NPK (mineral fertilization 70 kg N/ha; 40 kg P/ha; 120 kg K/ha), mycorrhizal substrate (AMF—arbuscular mycorrhizal fungi), NPK + AMF, manure before planting, NPK + manure before planting, BioIlsa, NPK + BioIlsa, BF-Ecomix, NPK + BF-Ecomix, Ausma, NPK + Ausma. The aim of the study was to assess the nutritional status of the two cultivars after long-term use of mineral fertilizers, organic fertilizers, biofertilizers and biostimulants under Polish conditions in soil with a low organic matter (SOM) content prone to acidification. AMF, organic fertilizers and biostimulants were not a sufficient alternative to mineral fertilizers, especially with regard to N supply. BF-Ecomix treatment increased the content of Mg in the soil and the soil pH value. Regular use of NPK fertilization increased the concentration of leaf N and K, but did not improve the nutritional status of plants with P, despite doubling its content in the soil compared to control. NPK fertilizers worsened the availability and accumulation of Mg and caused soil acidification, but resulted in a slight increase in total soil N and SOM. No significant differences were noted in the mineral status of both cultivars under the same fertilization treatments but liming improved the leaf Ca status in ‘Solaris’. Fertilization of grapevines, which have started to be cultivated in Poland due to the warming climate, requires further study. Mineral fertilization should not be routine, but rather constantly readjusted, taking into account the soil fertility and mineral status of plants, in order to use the nutrients more effectively and avoid their unfavorable effects on plants and soil. Full article