Bacillus tequilensis is a Gram-positive, endospore-forming bacterium with significant roles in agriculture and biotechnology. It enhances plant growth via phytohormone synthesis, nutrient solubilization, and antimicrobial activity against pathogens. Additionally, it contributes to bioremediation by degrading organic pollutants and produces industrially relevant enzymes. Its resilience to environmental stress underscores its potential for applications in sustainable agriculture, bioprocessing, and environmental remediation. < Microbial Species Bacillus tequilensis Bacillus tequilensis is a Gram-positive, endospore-forming bacterium with significant roles in agriculture and biotechnology. It enhances plant growth via phytohormone synthesis, nutrient solubilization, and antimicrobial… Show More Strength 1 x 10⁸ CFU per gram / 1 x 10⁹ CFU per gram Product Enquiry Download Brochure Benefits Soil Health Improvement Improves soil health by promoting organic matter decomposition and nutrient cycling, contributing to sustainable agriculture practices. Biocontrol Agent Bacillus tequilensis acts as a biocontrol agent, suppressing plant pathogens through the production of antimicrobial compounds. Stress Tolerance Helps plants withstand various environmental stresses, including drought and salinity, by inducing stress tolerance mechanisms. Plant Growth Promotion Enhances plant growth by producing growth-promoting substances such as phytohormones and siderophores, facilitating nutrient uptake. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Title: The Genus Bacillus: Applications and Biotechnological Potential https://www.intechopen.com/chapters/76175 Relevance: Provides a broad overview of the biotechnological potential of various Bacillus species, including their roles in plant growth promotion, biocontrol, and bioremediation. Offers context for the broader impact of Bacillus in sustainable agriculture and environmental management. Title: Bacillus tequilensis as a broad-spectrum antifungal agent against phytopathogenic fungi https://pubmed.ncbi.nlm.nih.gov/32358811/ Relevance: This study details the antifungal properties of Bacillus tequilensis, showcasing the effectiveness of this bacterial strain in combating various plant pathogens. This provides a scientific basis for incorporating it into biocontrol products. Title: Draft Genome Sequence of Bacillus tequilensis Strain ZSB20, an Endophytic Diazotroph with Antimicrobial Activity, Isolated from Grape Roots https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5664934 Relevance: Provides genomic evidence for the diazotrophic (nitrogen-fixing) and antimicrobial capabilities of Bacillus tequilensis, validating its role as a beneficial endophyte for promoting plant health. Title: Plant Growth Promoting Potential of Bacillus tequilensis and Bacillus amyloliquefaciens Isolated from Saline Soil https://www.researchgate.net/publication/344037808_Plant_Growth_Promoting_Potential_of_Bacillus_tequilensis_and_Bacillus_amyloliquefaciens_Isolated_from_Saline_Soil Relevance: It shows the isolation of B. tequilensis from saline soil and its ability to promote plant growth under salt stress conditions, this study supports its use in salinity management and improving crop yields in salt-affected areas. Title: Characterization of the Biosurfactant Produced by Bacillus tequilensis and Its Application in Enhanced Oil Recovery. https://www.proquest.com/openview/4f200c3b1fdc247c90d566d7d4a03f7c/1?pq-origsite=gscholar&cbl=18750&diss=y Relevance: This article characterizes the biosurfactant produced by B. tequilensis and explores its application in enhanced oil recovery. It offers insight into the surface-active properties of B. tequilensis, such as reducing surface and interfacial tension. Mode of Action Bacillus tequilensis exhibits a variety of modes of action, primarily centered around antimicrobial activity and the induction of plant resistance . Here's a breakdown of the key mechanisms: 1. Production of Antimicrobial Substances: B. tequilensis can produce various secondary metabolites with antimicrobial properties. These can include: Lipopeptides and biosurfactants: These compounds can disrupt the cell membranes of pathogenic fungi and bacteria, leading to leakage of cellular contents and cell death. Examples include iturins and fengycins. Bacteriocins: These are proteinaceous toxins produced by bacteria to inhibit the growth of similar or closely related bacterial strains. Volatile Organic Compounds (VOCs): Certain VOCs produced by B. tequilensis have demonstrated antifungal activity by inhibiting spore formation and germination and altering the cell morphology of pathogens. Enzymes: Production of lytic enzymes like chitinase, protease, and cellulase can degrade the cell walls of fungal pathogens. Other Antibiotic Compounds: Novel antibiotic agents like pyrrolo[1,2-a]pyrazine-1,4-dione,hexahydro, have been isolated from B. tequilensis with activity against multi-drug resistant bacteria. 2. Induction of Plant Resistance (Induced Systemic Resistance - ISR): B. tequilensis can trigger defense mechanisms in plants, making them more resistant to pathogen attacks. This can involve: Activation of the phenylpropanoid pathway: This pathway leads to the synthesis of various defense-related compounds like lignin and phenolic compounds, which strengthen plant cell walls and have antimicrobial properties. Enhancement of defense-related enzyme activities: B. tequilensis can induce the activity of enzymes such as phenylalanine ammonia-lyase (PAL), cinnamate 4-hydroxylase (C4H), 4-coumarate CoA ligase (4CL), polyphenol oxidase (PPO), superoxide dismutase (SOD), catalase (CAT), and peroxidase (POD). These enzymes play crucial roles in plant defense responses. Stimulation of plant growth and development: Some strains of B. tequilensis can produce indole-3-acetic acid (IAA), a plant hormone that promotes root growth and overall plant vigor, indirectly contributing to disease resistance. 3. Competition: B. tequilensis can compete with pathogenic microorganisms for essential nutrients and space in the plant rhizosphere or on plant surfaces, limiting pathogen colonization and growth. 4. Biofilm Formation: The ability of Bacillus species to form biofilms on plant roots can create a protective barrier against pathogen invasion and further infection. Additional Info Target pests: Fusarium wilt of tomato, leaf-spot disease of banana plants Recommended Crops: Tomato, banana, rice. Compatibility: Compatible with Bio Pesticides, Bio Fertilizers, and Plant growth hormones but not with chemical fertilizers and chemical pesticides. Shelf Life: Stable within 1 year from the date of manufacturing. Packing: We offer tailor-made packaging as per customers' requirements. Dosage & Application The water-soluble powder formulation of Bacillus tequilensis is engineered for ease of use and maximum efficacy across a wide range of environmental and agricultural applications. Leveraging its robust biosurfactant production, cellulolytic activity, and broad-spectrum biocontrol potential, B. tequilensis is an ideal choice for bioremediation, pest control, organic matter recycling, and sustainable crop management. General Guidelines Preparation: Dissolve the required quantity of B. tequilensis powder in clean, non-chlorinated water. Avoid chlorinated water, as it may reduce bacterial viability and activity. Use a container or tank with adequate mixing to ensure complete dissolution. Activation Time: Allow the solution to rest for 15–30 minutes after mixing. This activates the microbial population and optimizes performance upon application. Application Timing:Apply early in the morning or late in the afternoon to minimize exposure to high temperatures and UV radiation, both of which can diminish bacterial efficacy. Dosage Recommendations 1. Bioremediation of Soil and Water Target: Hydrocarbons, heavy metals, and organic pollutants. Dosage: Dissolve 1–2 kg of powder in 200–400 liters of water per hectare for soil application. For water bodies, use 5–10 g per cubic meter of contaminated water. Application: Spray uniformly over contaminated soil or introduce directly into the polluted water body. B. tequilensis produces biosurfactants that enhance the breakdown and bioavailability of hydrocarbons and other pollutants . Frequency: Reapply every 3–4 weeks until remediation targets are met. 2. Pest and Disease Biocontrol in Agriculture Target: Soil-borne pathogens, fungal diseases, and certain pests. Dosage: Dissolve 500 g of powder in 100 liters of water per hectare. Application: Foliar Spray: Apply evenly over plant foliage to suppress fungal and bacterial pathogens. Soil Drench: Apply directly to the root zone to control soil-borne diseases and enhance root health. Frequency: Reapply every 2–3 weeks or as needed based on disease pressure. B. tequilensis is effective against a broad spectrum of plant pathogens, including Magnaporthe oryzae , Phytophthora nicotianae , Verticillium dahliae , and othes. 3. Nutrient Cycling and Organic Matter Decomposition Target: Soil enrichment, compost acceleration, and nutrient recycling. Dosage: Dissolve 1 kg of powder in 200 liters of water per hectare. Application: Apply as a soil drench or through fertigation systems. B. tequilensis exhibits strong cellulolytic activity, accelerating the breakdown of plant residues and improving soil fertility Frequency: Apply at the start of the growing season and repeat every 4–6 weeks for sustained soil health benefits. 4. Hydrocarbon and Industrial Waste Biodegradation Target: Hydrocarbons and organic waste in soil or industrial effluents. Dosage: Dissolve 1–2 kg of powder in 200–400 liters of water per hectare. Application: Spray over contaminated sites or introduce into waste streams. The biosurfactant-producing capacity of B. tequilensis enhances the emulsification and breakdown of recalcitrant pollutants. Frequency: Reapply every 4 weeks until remediation is complete. 5. Abiotic Stress Alleviation in Crops Target: Salinity and drought stress in sensitive crops. Dosage: 500 g–1 kg per hectare, dissolved in adequate water. Application: Soil drench or seed treatment. B. tequilensis has demonstrated efficacy in improving crop growth, nutrient uptake, and physiological resilience under saline and drought conditions, notably in rice and other cereals . Frequency: Apply at planting and repeat at key crop stages. Best Practices & Additional Notes For maximum biocontrol efficacy , consider integrating B. tequilensis with compatible carriers (e.g., biochar) or in consortia with other Bacillus species to enhance disease suppression and soil health 10 . Thermal and pH Stability: B. tequilensis metabolites remain active under a range of temperatures and acidic conditions, making it suitable for diverse environments. Environmental Safety: B. tequilensis is non-toxic to plants, animals, and humans when used as directed, supporting sustainable and eco-friendly management practices. Summary: Bacillus tequilensis is a versatile, science-backed microbial solution for bioremediation, crop protection, soil fertility, and stress mitigation. Its robust biosurfactant and enzyme production, broad-spectrum pathogen suppression, and adaptability to challenging environments make it a valuable tool for modern agriculture and environmental management. For technical support or custom application protocols, please contact us . FAQ What is Bacillus tequilensis ? Bacillus tequilensis is a species of bacteria belonging to the genus Bacillus . It's known for its diverse metabolic capabilities and its potential applications in various fields, particularly in agriculture as a biocontrol agent. What are the main modes of action of Bacillus tequilensis ? The primary modes of action include: Production of Antimicrobial Substances: Synthesizing compounds like lipopeptides, bacteriocins, volatile organic compounds (VOCs), and lytic enzymes that directly inhibit or kill pathogens. Induction of Plant Resistance (ISR): Triggering the plant's own defense mechanisms to become more resistant to diseases. Competition: Outcompeting pathogenic microorganisms for nutrients and space. Biofilm Formation: Creating a protective barrier on plant roots against pathogen invasion. How does Bacillus tequilensis produce antimicrobial substances? B. tequilensis can produce a range of compounds, including: Lipopeptides and biosurfactants: Disrupting pathogen cell membranes. Bacteriocins: Inhibiting the growth of other bacteria. Volatile Organic Compounds (VOCs): Exhibiting antifungal activity. Lytic Enzymes (e.g., chitinase, protease): Degrading pathogen cell walls. * Other Antibiotics: Novel compounds with antimicrobial properties. How does Bacillus tequilensis induce plant resistance? It triggers the plant's defense system through mechanisms such as: Activation of the phenylpropanoid pathway: Leading to the production of defense-related compounds. Enhancement of defense-related enzyme activities: Boosting enzymes involved in plant immunity. * Stimulation of plant growth and development: Indirectly contributing to resistance through improved plant health. Can Bacillus tequilensis help plants grow? Yes, some strains can produce indole-3-acetic acid (IAA), a plant hormone that promotes root growth and overall plant vigor. This can indirectly enhance the plant's ability to withstand stress, including pathogen attacks. What makes Bacillus tequilensis a good candidate for biocontrol? Its multiple modes of action, including direct antimicrobial activity and the ability to induce plant resistance, make it effective against a range of plant pathogens. Additionally, Bacillus species are generally known for their ability to colonize the rhizosphere and their relative safety. Is Bacillus tequilensis safe for the environment? When used as a biocontrol agent, Bacillus tequilensis is generally considered environmentally friendly as it offers a more sustainable alternative to synthetic pesticides. However, specific formulations and application methods should always be evaluated for their environmental impact. Where can Bacillus tequilensis be found? Bacillus species are widely distributed in nature and can be found in soil, water, and associated with plants. Bacillus tequilensis was initially isolated from a tequila fermentation process, hence its name. Are there different strains of Bacillus tequilensis with varying modes of action? Yes, different strains within the Bacillus tequilensis species can exhibit variations in their metabolic capabilities and the specific antimicrobial compounds they produce, as well as their effectiveness in inducing plant resistance. How is Bacillus tequilensis applied in agriculture? It can be applied through various methods, including seed treatments, soil drenching, and foliar sprays, depending on the target pathogen and the crop. Related Products Ampelomyces quisqualis Bacillus subtilis Chaetomium cupreum Fusarium proliferatum Lactobacillus plantarum Pediococcus pentosaceus Pseudomonas spp. Trichoderma harzianum More Products Resources Read all

Nano Zinc Fertilizers is a customized liquid zinc nutrient mix containing particulates of ionized zinc embedded in a colloidal amino acid matrix; for use in agricultural fertilization programs and animal feed supplements. Nano Zinc Fertilizer Recommended to be used for Rice, Sugarcane, Orchards, Vegetables, Medicinal and Aromatic plants. Nano Zinc Fertilizer is a customized liquid zinc nutrient mix containing particulates of ionized zinc embedded in a colloidal amino acid matrix; for use in agricultural fertilization programs and animal feed supplements. It is an important component of various enzymes that are responsible for driving many metabolic reactions in all crops. Nano Zn is an essential micronutrient for plant life. Its primary function is to help with several biochemical processes in the plant, including chlorophyll production and membrane integrity. Benefits Highly used for the treatment of zinc deficiency and stimulates plant growth Essential to carbohydrate metabolism A functional cofactor of a large number of enzymes including auxins (plant growth hormones) Essential to protein synthesis and internodal elongation (stem growth) Functions as a metal activator for plant enzymes, particularly growth regulators Nano Technology will help making Zn in small quantities to replace of bags of Zn Fertilizer Composition/Technical Specifications Dosage and method of Application In Agriculture: As Zn Source: 10L Nano Zn can replace 100 kg Zinc sulphate monohydrate ZnSO4.H2) Foliar Spray: Dissolve 0.5 ml in a liter of water and spray on both the surface of the leaves. Can be sprayed anytime. Soil Application: 2.5 L per acre and apply during sowing or transplanting In Animal Feeds: 150 ml per 1 Ton of feed or 1 ml per 1L in drinking water Compatibility Compatible with chemical fertilizers and chemical pesticides. Shelf Life & Packaging Shelf life : Best before 24 months, Stored in room temperature. Packaging : 25 Liters Symptoms of Zinc Deficiency Reduced root growth and activity Lower microbial activity in the soil which decreases zinc release from soil organic matter Plants are stunted and shows dusty brown spots on upper leaves New leaves are often smaller and narrower Show delayed maturity, short internodes and a decrease in leaf size Presence of mottled leaves with irregular chlorotic areas. For more biofertilizers visit Nano fertilizers Downloads Product Information Click here for Product Enquiry

Rhizophagus intraradices (previously Glomus intraradices) is an arbuscular mycorrhizal fungus used in agriculture, that improves root structure enhances plant nutrient uptake, especially phosphorus, improving plant growth, stress resilience, and soil health in sustainable agriculture. < Microbial Species Rhizophagus Intraradices Rhizophagus intraradices (previously Glomus intraradices) is an arbuscular mycorrhizal fungus used in agriculture, that improves root structure enhances plant nutrient uptake, especially phosphorus, improving plant… Show More Strength 245 Active Spores per gram Product Enquiry Download Brochure Benefits Improved Soil Health Hyphal networks bind soil particles, promoting soil structure, aeration, and moisture retention, creating healthier, more resilient environments for plant roots. Reduced Fertilizer Dependence Improved nutrient efficiency allows plants to thrive with less fertilizer, supporting sustainable farming practices and decreasing potential soil and water pollution. Increased Drought Resistance Extending root surface area boosts water absorption, helping plants endure drought conditions, enhancing resilience, and reducing water stress. Enhanced Nutrient Uptake Improves nutrient access, especially phosphorus, by forming hyphal networks that extend beyond plant roots, increasing nutrient availability and uptake. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Improves growth and phosphorus uptake in contaminated soil Inoculation with R. intraradices significantly enhanced soybean growth, phosphorus uptake, and grain yield even in heavy metal-contaminated soils ( Adeyemi et al., 2021 ). Broad agricultural benefits and soil health contributions A comprehensive review highlighted the species' roles in nutrient cycling, improved water retention, glomalin production, and overall support for sustainable agriculture ( Onyeaka et al., 2024 ). Enhanced nutrient uptake and microbial community structure Field experiments with maize showed that R. intraradices increased phosphorus and nitrogen uptake, biomass, and improved soil microbial biomass when combined with earthworms ( Li et al., 2013 ). Remediation and soil improvement in polluted environments Combining R. intraradices with Solanum nigrum improved cadmium retention in roots, boosted soil enzyme activity, and enhanced microbial diversity under heavy metal stress ( Wang et al., 2025 ). Improved drought tolerance and antioxidant activity Inoculated finger millet seedlings showed improved phosphorus uptake, chlorophyll content, and stress tolerance indicators such as higher antioxidant levels and reduced oxidative damage (Tyagi et al., 2021) . Mode of Action 1. Host Recognition and Root Colonization Rhizophagus intraradices , a species of arbuscular mycorrhizal fungus (AMF) in the phylum Glomeromycota , initiates symbiosis through a sophisticated chemical signaling exchange with host plants. Root exudates, particularly strigolactones , trigger spore germination and hyphal branching. In response, R. intraradices produces Myc-LCOs (Mycorrhizal lipochitooligosaccharides) , which activate host plant receptors and initiate symbiotic signaling pathways via the common symbiosis signaling pathway (CSSP) . Once recognition is achieved, the fungus penetrates the root epidermis and cortex via appressoria , establishing intraradical colonization . Within cortical cells, it forms arbuscules , finely branched hyphal structures that serve as the interface for bi-directional nutrient exchange. In some host species, vesicles are also formed, acting as lipid-rich storage and reproductive structures. Source : Kumar, Sanjeev. (2018). In vitro cultivation of AMF using Root Organ Culture: factory of biofertilizers and secondary metabolites production. 2. Nutrient Foraging and Transfer The most direct agronomic benefit of R. intraradices lies in its capacity to enhance nutrient acquisition: The fungus develops an extensive extraradical hyphal network that significantly increases the absorptive surface area of the root system, accessing nutrients beyond the rhizosphere depletion zone . Key nutrients mobilized include phosphorus (Pi) , zinc (Zn) , copper (Cu) , and other micronutrients, often bound in forms that are otherwise unavailable to plants. High-affinity phosphate transporters (e.g., GintPT ) in fungal hyphae facilitate Pi uptake, which is then translocated via the fungal cytoskeleton to the arbuscules. Inside the arbuscule interface, nutrient exchange occurs via a periarbuscular membrane , where plant Pi and metal transporters (e.g., PT4 ) retrieve the nutrients. In return, the plant supplies the fungus with photosynthetically derived carbon , mainly in the form of hexoses , transported through plant sugar transporters , supporting fungal metabolism and reproduction. Khan, Yaseen, Sulaiman Shah, and Tian Hui. 2022. " The Roles of Arbuscular Mycorrhizal Fungi in Influencing Plant Nutrients, Photosynthesis, and Metabolites of Cereal Crops—A Review" Agronomy 12, no. 9: 2191. 3. Abiotic Stress Alleviation R. intraradices significantly modulates plant physiological responses under abiotic stress conditions: Enhances water acquisition through extended hyphal reach and improved root hydraulic conductivity. Increases osmoprotectant synthesis , including proline , glycine betaine , and soluble sugars , aiding in osmotic adjustment under drought and salinity stress. Activates antioxidant enzyme systems , including superoxide dismutase (SOD) , catalase (CAT) , and ascorbate peroxidase (APX) , reducing oxidative damage from ROS generated during stress. Influences the synthesis and signaling of phytohormones such as abscisic acid (ABA) , jasmonic acid (JA) , salicylic acid (SA) , and auxins , which regulate stress adaptation, stomatal closure, and root architecture. 4. Soil Aggregation and Health The extraradical hyphae of R. intraradices play a critical role in soil structure and fertility : Secrete glomalin-related soil proteins (GRSPs) that stabilize soil aggregates by binding mineral particles and organic matter. Improve soil porosity , water infiltration , and bulk density , contributing to enhanced root penetration and aeration. Support carbon sequestration by promoting stable soil organic carbon pools. Increase microbial biomass and enzymatic activity, such as phosphatases , ureases , and dehydrogenases , which further enhance nutrient cycling and microbial community function. 5. Biotic Stress Resistance and Pathogen Suppression R. intraradices contributes to plant immunity and disease resistance through several pathways: Competes with soil pathogens for space and resources in the rhizosphere and root cortex. Activates induced systemic resistance (ISR) via jasmonate and ethylene signaling pathways, enhancing the plant’s defense readiness. Alters rhizosphere microbiome composition , often increasing populations of beneficial microorganisms (e.g., Pseudomonas , Trichoderma ) that further antagonize pathogens. Reduces the translocation of heavy metals and xenobiotics to aerial parts, providing a protective buffer in contaminated soils. 6. Ecological and Agronomic Integration In sustainable agriculture, R. intraradices is increasingly applied as a bioinoculant , either alone or in combination with other beneficial microbes. Its efficacy depends on: Soil conditions (pH, organic matter, nutrient availability) Host plant genotype and mycorrhizal compatibility Co-inoculation strategies (e.g., with nitrogen-fixing bacteria like Azospirillum brasilense ) Reduction in synthetic fertilizer inputs, which can suppress AMF colonization when in excess Additional Info Product Specifications Strength: customisable Formulation: customisable Purity: High-quality inoculum with verified spore viability Storage and Handling Store in a cool, dry place away from direct sunlight and extreme temperatures. Optimal storage temperature is 4-25°C (39-77°F). Keep container tightly sealed when not in use. Shelf life is 12 months when stored properly. Avoid exposure to fungicides or excessive heat which may reduce spore viability. Best Practices Apply to moist soil for optimal spore germination Ensure direct contact between inoculant and plant roots Avoid over-fertilization, especially with phosphorus, which can suppress mycorrhizal colonization Combine with organic matter amendments to enhance fungal establishment Use within the same growing season after opening for maximum effectiveness Environmental Conditions R. intraradices thrives in well-aerated, slightly acidic to neutral soils (pH 5.5-7.0). The fungus is naturally adapted to diverse soil types and climatic conditions, making it suitable for global agricultural applications. Performance is optimized in soils with moderate organic matter content and adequate moisture. Safety Non-toxic and safe for humans, animals, and the environment. Certified for use in organic agriculture by various international certification bodies. Contains only naturally occurring beneficial fungi with no genetically modified organisms. Dosage & Application Application Rates for Different Agricultural Systems For Field Crops (Hectare-based application): Standard field application: 60 g per hectare High-intensity farming: Up to 100 g per hectare for optimal colonization Maize and cereal crops: 60–100 g/ha mixed with seed or applied at sowing Legume crops (soybean, chickpea, lentil): 60 g/ha, compatible with rhizobial inoculants Horticultural crops (vegetables, fruits): 30–50 g per hectare For Specialized Applications: Hydroponic systems: 1 g per plant or 580 propagules per liter applied via subirrigation Greenhouse nurseries and potting: 3 g per square meter of growing area Tissue culture and micropropagated plants: 0.5–1.0 g per seedling during hardening stage Cuttings and propagation material: 0.5 g per cutting at rooting medium Turf and ornamental applications: 50–100 g per 1000 m² Optimal Spore Density and Colonization Rates Research indicates that optimal inoculation requires a minimum threshold for effective colonization: Minimum effective spore density: 2–3 spores per seed or seedling for adequate colonization establishment Optimal spore density: 5–6 spores per seed results in superior root colonization rates (75–84%) and maximal plant vigor Application strength: The product contains 245 active spores per gram, ensuring consistent and reliable inoculum quality Colonization timeline: Initial root colonization typically occurs within 2–4 weeks; visible plant benefits manifest within 6–8 weeks; maximum benefits develop throughout the entire growing season Application Methods and Techniques Seed Treatment (Most Common) Mix R. intraradices inoculum with seeds immediately before sowing at a ratio of 60 g per hectare. Ensure uniform distribution for consistent field colonization. In-Furrow Application Apply 60 g per hectare directly into the planting furrow at sowing depth (5–8 cm). This method ensures close proximity of spores to germinating roots. Root Dip Method (Nurseries and Transplants) Suspend seedling roots in a slurry containing 3 g per square meter of growing area for 2–5 minutes before transplanting. This high-contact method accelerates colonization establishment. Subirrigation and Hydroponic Systems Dilute liquid inoculum (580 propagules/liter) in irrigation water and apply weekly through drip or subirrigation systems. Filter product to prevent emitter clogging. Soil Incorporation Mix inoculum into soil at 60 g per hectare 1–2 weeks before planting for field crops, allowing time for spore positioning. Foliar and Root Zone Drenching Apply via soil drenching at transplanting stage (10 mL per plant) for containerized crops and horticultural applications. Critical Application Considerations Phosphorus Management High soil phosphorus levels (>50 ppm) suppress AMF colonization and reduce symbiotic effectiveness. When using R. intraradices, reduce phosphorus fertilizer applications and rely on the fungus to mobilize existing soil phosphorus reserves. Combination treatments of R. intraradices + 50% recommended phosphorus consistently outperform full-dose phosphorus alone. Fungicide and Chemical Interactions Avoid fungicide applications for at least 2–4 weeks post-inoculation to prevent suppression of colonization. Systemic fungicides are particularly damaging to AMF establishment. Coordinate all pesticide applications with agronomist recommendations considering AMF symbiosis. Soil Preparation and Timing Inoculate into well-prepared, slightly acidic to neutral soils (pH 6.0–7.5). Avoid waterlogged conditions immediately post-inoculation. Ideal soil moisture should be 60–70% of field capacity. Compatibility with Other Microorganisms R. intraradices generally works synergistically with beneficial bacteria (Bacillus spp., Azospirillum spp.) and other AMF species. Co-inoculation often produces superior results to single-organism application. Storage and Handling Store product in cool, dry conditions (4–15°C) in sealed containers away from light. Do not expose to temperatures above 25°C or to direct sunlight. Use within 12–24 months of manufacture for optimal viability; maintain storage conditions to preserve spore viability and germination potential. FAQ What is the new name for Glomus intraradices? The fungus formerly known as Glomus intraradices has been officially reclassified as Rhizophagus intraradices based on comprehensive molecular phylogenetic analysis. This taxonomic change, implemented following the 2010 reclassification by Schüßler and Walker, reflects advances in DNA sequencing technology and ribosomal RNA gene analysis that revealed the original genus assignment was incorrect. The genus Rhizophagus is more accurately aligned with the evolutionary lineage and morphological characteristics of this species. The reclassification was formally anchored through the International Culture Collection of Vesicular Arbuscular Mycorrhizal Fungi (INVAM) culture FL208, which represents the type strain and nomenclatural authority for the species. Important Note: It is critical to distinguish between two distinct species within the Rhizophagus genus: Rhizophagus intraradices (formerly Glomus intraradices, strain FL208 and related isolates) Rhizophagus irregularis (formerly known as Glomus irregulare and historically confused with R. intraradices, particularly the DAOM197198 reference strain) While historically conflated, phylogenetic and molecular analyses now clearly demonstrate these are separate species with different colonization characteristics and agricultural performance profiles. What is the use of Glomus intraradices (Rhizophagus intraradices)? R. intraradices serves as a plant growth-promoting arbuscular mycorrhizal fungus with diverse agricultural, horticultural, and environmental applications: Sustainable intensification of cereal crops (maize, wheat, rice, sorghum) with reduced fertilizer dependency Improved legume performance (soybean, chickpea, lentil) complementing nitrogen-fixing rhizobia Enhanced tuber and root crop yields (potato, cassava, carrots) with superior nutrient uptake and stress tolerance Horticultural Applications Nursery production of high-quality transplants with accelerated growth and disease resistance Fruit crop establishment (citrus, mango, avocado, berry crops) with improved root development Ornamental plant production with superior vigor and stress resilience Vegetable production (tomato, pepper, cucumber) supporting both conventional and organic systems Environmental Remediation Phytoremediation of heavy metal-contaminated soils through enhanced metal uptake capacity and soil enzyme activity Restoration of degraded mining sites and contaminated agricultural lands Coal mining site revegetation and ecosystem recovery Support for pioneer plant species establishment in marginal and disturbed environments Sustainable Agriculture Intensification Reduction of synthetic fertilizer inputs by 25–50% while maintaining or improving yields Support for organic farming systems seeking certified biological inputs Climate-smart agriculture through enhanced carbon sequestration and drought resilience Integrated pest management via natural disease suppression mechanisms Specialized Applications Micropropagated plant hardening and acclimatization protocols Hydroponic and soilless cultivation systems for high-value crops Biofortification programs improving micronutrient density in staple food crops Effects of Rhizophagus intraradices on Crops Research has documented comprehensive beneficial effects across diverse crop species: Nutrient Uptake and Growth Promotion Phosphorus uptake: 50–130% increase in plant-available phosphorus, enabling 25–50% reduction in phosphate fertilizer Nitrogen acquisition: Enhanced nitrogen uptake through both direct root absorption and fungal-mediated pathways Micronutrient availability: Improved zinc, copper, iron, and manganese bioavailability particularly important in calcareous and alkaline soils Biomass accumulation: Increased shoot and root dry matter by 15–40% depending on soil fertility and environmental conditions Root System Development Enhanced lateral root initiation and root hair density Increased root diameter and improved soil penetration capability Expanded root surface area (up to 100-fold expansion through hyphal networks) Modified root architecture supporting improved nutrient and water acquisition Yield and Productivity Grain yield: 10–35% yield increases in cereals (maize, wheat, rice) particularly under limiting nutrient or water availability Legume productivity: 20–30% increases in soybean, chickpea yields with complementary rhizobial inoculation Tuber production: 14.5% yield increases in cassava in phosphorus-deficient soils Horticultural crops: 25–35% increases in fruit number and mass in pepper, tomato, strawberry Stress Tolerance Enhancement Drought resilience: Maintained photosynthetic efficiency and leaf water potential under moderate to severe drought; 20–25% greater biomass than non-inoculated plants under water stress Salt tolerance: Enhanced ion selectivity and osmolyte accumulation mitigating salinity stress effects Heavy metal mitigation: Enhanced phytoextraction and phytostabilization of cadmium, lead, and arsenic; reduced toxic ion accumulation in shoots Cold and temperature stress: Improved cellular cryoprotectant accumulation and membrane integrity maintenance Disease and Pest Suppression Root-knot nematode biocontrol: Reduced Meloidogyne graminicola populations and symptoms in rice through enhanced plant defense activation Soil-borne pathogen suppression: Reduced incidence of Fusarium, Rhizoctonia, and other fungal root pathogens through competitive exclusion and defense enhancement Pest susceptibility reduction: Western corn rootworm larvae show reduced fitness on R. intraradices-colonized maize, facilitating biological pest control Soil Quality and Long-term Sustainability Soil aggregation: Enhanced water-stable aggregate formation improving soil structure and workability Organic matter stabilization: Glomalin accumulation supports 10–20-year soil organic matter persistence Microbial community enhancement: Increased beneficial soil microbial diversity and activity Carbon sequestration: Contribution to global carbon cycle with approximately 13 Gt CO₂e annually sequestered Crop-Specific Effects Rice: 35–50% increase in grain yield with improved phosphorus and nitrogen uptake; enhanced disease resistance to bacterial leaf blight (Xanthomonas oryzae pv. oryzae) Maize: 20–35% yield increase with enhanced water use efficiency; reduced Western corn rootworm damage through modified rhizosphere chemistry Soybean: 15–30% yield improvement with complementary rhizobial associations; enhanced phosphorus uptake in continuous cropping systems Wheat: Significant phosphorus uptake enhancement and improved grain quality parameters Citrus/Lemon: Enhanced lateral root formation and phosphate transporter gene expression; improved water uptake capacity Tomato: 25–35% increase in fruit yield and quality; improved water stress tolerance during critical fruit development stages Saffron: 25% increase in total chlorophyll content; enhanced daughter corm production and stigma development Finger Millet: 29% increase in phosphorus and chlorophyll under drought stress; 7% growth improvement under severe water limitation Related Products Glomus mosseae Serendipita indica More Products Resources Read all

Indogulf BioAg is a trusted manufacturer of nutraceuticals, offering herbal extracts, probiotics, and natural health supplements designed to support immunity and overall wellness. Nutraceuticals Fermentation-Driven Health Supplements IndoGulf BioAg supplies the nutraceutical industry with high-quality probiotic cultures and fermentation-derived bioactives, including vitamins, enzymes, and organic acids—produced under food-grade conditions and backed by rigorous quality control for safe, effective use in supplements and functional foods. Contact us IndoGulf BioAg extends its fermentation and microbial cultivation expertise to the nutraceuticals and functional foods industry. IndoGulf BioAg brings its microbial cultivation expertise to the growing nutraceutical and functional foods market. We specialize in the large-scale production of probiotic strains such as Lactobacillus, Bifidobacterium, and Saccharomyces boulardii, which are widely used for digestive and immune health. Cultivated under food-grade or GMP-certified conditions, these probiotics are available as concentrated powders or liquid suspensions, ready for inclusion in capsules, sachets, or functional foods. Our fermentation systems ensure high colony-forming unit (CFU) counts and consistent purity across every batch. Beyond live microbes, our advanced fermentation platforms are used to produce bioactive compounds that support various health goals. These include B-complex vitamins, vitamin K2, digestive enzymes, organic acids, and antioxidant molecules—all derived naturally through controlled microbial processes. Compared to synthetically manufactured ingredients, our fermentation-based compounds are often more bioavailable and compatible with clean-label product strategies. We also offer extraction and purification services to meet specific concentration, formulation, or regulatory needs. All IndoGulf BioAg ingredients undergo rigorous safety and quality testing—ensuring pathogen-free, allergen-free, and performance-verified outputs. From activity assays to stability profiling, we provide comprehensive documentation to support nutraceutical compliance. Whether you're developing a new probiotic line or enhancing your existing functional food products, IndoGulf BioAg offers a trusted partnership grounded in biotech innovation and a deep understanding of consumer health trends. Benefits to Nutraceuticals Probiotic Production Scaled-up cultivation of beneficial microbes with high viability, delivered in stable form factors for use in capsules, tablets, or functional foods. Bioactive Metabolites Fermentation-based manufacturing of vitamins, amino acids, and enzymes offers naturally-derived actives for supplements, often with higher bioavailability. Quality & Purity Manufacturing processes adhere to strict quality standards (including cGMP for food supplements), ensuring products are safe, contaminant-free, and meet label claims for potency. Custom Strains & Blends Ability to develop unique probiotic blends or tailored fermentation processes to create proprietary ingredients that differentiate your product in the market. R&D Collaboration Our scientific team can co-develop and optimize new nutraceutical concepts, providing technical insight from strain selection to ingredient stabilization for maximum effectiveness. Fuel your nutraceutical innovation with our microbial manufacturing prowess. Contact IndoGulf BioAg to source high-quality probiotics and fermented nutraceutical ingredients or to collaborate on developing your next health product. Contact us 1 2 3 ... 100 1 ... 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 ... 100

Effective Insecta Repel by Indogulf BioAg. Natural insect control for healthier crops. 100% organic, eco-friendly, and certified. Trusted by growers globally. < Plant Protect Insecta Repel Insecta Repel uses Bti toxins to target larvae of mosquitoes, fungus gnats, and blackflies, offering effective control with minimal environmental impact. Product Enquiry Download Brochure Benefits Effective Mosquito Control Targets and controls mosquito larvae, reducing disease transmission risks. Residue-Free Leaves no harmful residues, safe for organic farming and human health. Selective Action Minimizes impact on non-target organisms, ensuring environmental safety. Biological Control Utilizes natural properties of Bti for targeted pest control and biodiversity preservation. Substance Amount Bacillus thuringiensis var. israelensis spores (Viable Spore count: 30 x 10⁶ / ml min., Potency: 630 ITU/mg min.) 5.00% w/w Delta endotoxin 2.00% w/w Sodium Alginate 2.00% w/w Glycerol 20.00% w/w Liquid Paraffin 10.00% w/w Citric Acid 0.10% w/w Sodium Benzoate 0.20% w/w Congo Red 0.05% w/w Water (sterilized) Q.S. Total 100.00% w/w Composition Dosage & Application Key Benefits FAQ Additional Info Additional Info Shelf Life & Packaging Storage: Store in a cool, dry place at room temperature Shelf Life: 24 months from the date of manufacture at room temperature Packaging: 1 kg pouch & bottle / 1 litre bottle / Bulk order FAQ Content coming soon! Key Benefits Content coming soon! Dosage & Application Liquid Dosage: Wettable Powder Formulation (18,000 IU/mg): Related Products Trichoderma viride Beauveria bassiana Bloom Up Flyban Larvicare Mealycare Metarhzium Anisopliae Mitimax More Products Resources Read all

Agricultural Probiotics, Natural lawn fertilizers, Biological Inoculants, Mycorrhiza, biofertilizer, bio-fertilizer, nitrogen suppliers and manufacturers in USA & Canada. Thank you! We've received your request, our associate will get in touch with you soon. Go to Home

Herbaspirillum frisingense is used in agriculture to promote plant growth by fixing nitrogen and producing plant hormones, enhancing crop yields and soil health. < Microbial Species Herbaspirillum frisingense Herbaspirillum frisingense is used in agriculture to promote plant growth by fixing nitrogen and producing plant hormones, enhancing crop yields and soil health. Strength 1 x 10⁸ CFU per gram / 1 x 10⁹ CFU per gram Product Enquiry Download Brochure Benefits Nitrogen Fixation Herbaspirillum frisingense fixes atmospheric nitrogen into ammonia, which enhances nitrogen availability for plants, supporting their growth and development. Plant Growth Promotion Herbaspirillum frisingense produces phytohormones like auxins and cytokinins, which stimulate root growth and increase the efficiency of nutrient and water uptake. Biological Control It exhibits biocontrol properties against plant pathogens by producing antibiotics and siderophores that inhibit pathogen growth, thereby protecting plants from diseases. Phosphate Solubilization It solubilizes phosphate in the soil, making it more accessible to plants, which improves their phosphorus uptake and overall nutrient status. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Content coming soon! Mode of Action Content coming soon! Additional Info Recommended Crops: Cereals, Millets, Pulses, Oilseeds, Fibre Crops, Sugar Crops, Forage Crops, Plantation crops, Vegetables, Fruits, Spices, Flowers, Medicinal crops, Aromatic Crops, Orchards, and Ornamentals. Compatibility: Compatible with Bio Pesticides, Bio Fertilizers, and Plant growth hormones but not with chemical fertilizers and chemical pesticides. Shelf Life: Stable within 1 year from the date of manufacturing. Packing: We offer tailor-made packaging as per customers' requirements. Dosage & Application Seed Coating/Seed Treatment: Coat 1 kg of seeds with a slurry mixture of 10 g of Herbaspirillum Frisingense and 10 g of crude sugar in sufficient water. Dry the coated seeds in shade before sowing or broadcasting in the field. Seedling Treatment: Dip seedlings into a mixture of 100 grams of Herbaspirillum Frisingense with sufficient water. Soil Treatment: Mix 3-5 kg per acre of Herbaspirillum Frisingense with organic manure or fertilizers. Incorporate into the soil during planting or sowing. Irrigation: Mix 3 kg per acre of Herbaspirillum Frisingense in water and apply through drip lines. FAQ Content coming soon! Related Products Acetobacter xylinum Azospirillum brasilense Azospirillum lipoferum Azospirillum spp. Azotobacter vinelandii Beijerinckia indica Bradyrhizobium elkanii Bradyrhizobium japonicum More Products Resources Read all

Beneficial bacteria and fungi promote plant growth through multiple, well-documented physiological and biochemical mechanisms. These microorganisms interact with plant roots and the surrounding rhizosphere to enhance nutrient acquisition, stimulate growth, and improve resilience against stress and disease. Biofertilizers Optimized Microbial Power for Sustainable Crop Nutrition Beneficial bacteria and fungi promote plant growth through multiple, well-documented physiological and biochemical mechanisms. These microorganisms interact with plant roots and the surrounding rhizosphere to enhance nutrient acquisition, stimulate growth, and improve resilience against stress and disease. Contact us Microbial Mechanisms That Power Plant Growth Phosphate Solubilization & Mineralization Process: Microbes solubilize inorganic phosphate (e.g. tricalcium phosphate) via secretion of low molecular weight organic acids (citric, gluconic) and enzymatic hydrolysis of organic P compounds. Bacteria: Bacillus megaterium , Pseudomonas putida Fungi: Penicillium bilaii , Aspergillus niger Benefit: Increases phosphorus bioavailability, particularly in high pH or phosphorus-fixing soils. All Arbuscular Mycorrhizal Fungi (AMF) Symbiosis Biocontrol & Induced Systemic Resistance (ISR) Biological Nitrogen Fixation Phosphate Solubilization & Mineralization Phytohormone Biosynthesis Siderophore Production for Iron Mobilization Soil Structure & Rhizosphere Engineering Stress Alleviation via ACC Deaminase Combined Effects Together, these microbial functions enhance: Nutrient use efficiency (NUE) Crop yield and quality Abiotic stress resilience Biotic stress suppression Soil health and regeneration Interested in a functional blend tailored to your crops and soils? Contact us for a field-proven microbial formulation aligned with your agronomic objectives. IndoGulf BioAg’s biofertilizer range includes nitrogen-fixing bacteria, phosphate-solubilizing microbes, potassium-mobilizing strains, plant growth-promoting rhizobacteria (PGPR), as well as symbiotic mycorrhizal fungi. All products are backed by scientific research and field trials, ensuring consistent performance across diverse soils and climates. Farmers can apply our biofertilizers via seed coating, soil drench, or fertigation, seamlessly integrating into existing cultivation practices for improved fertility and reduced chemical input. Improved Soil Fertility Replenishes soil with natural nutrients and organic matter, enhancing long-term soil health and structure. Higher Yields Increases crop productivity by boosting nutrient uptake and stimulating stronger root and shoot development. Reduced Chemical Dependence Lowers the need for synthetic fertilizers and pesticides, cutting input costs and minimizing environmental runoff. Resilience & Growth Promotion Microbial partners produce vitamins and phytohormones (like auxins and gibberellins) that improve plant vigor and tolerance to stress (drought, pests). Eco-Friendly Farming 100% natural and safe for crops, soil, and beneficial insects – supporting sustainable and organic farming certifications. Segments We Focus on Natural, microbe-based solutions that boost nutrient availability, improve soil health, and support sustainable plant growth—without the need for synthetic inputs. Root Enhancers Strengthen your plants from the ground up with our root enhancers, promoting deep, resilient root systems for healthier growth and improved nutrient uptake. View Collection Soil Enhancers Our Soil Fertilizers are designed to replenish essential nutrients and enhance soil fertility, providing plants with the nourishment they need for vigorous growth and abundant yields. Formulated with premium-quality ingredients, including organic matter and micronutrients, our fertilizers promote soil health, improve soil structure, and support sustainable agriculture practices. View Collection Microbial Blends Restore soil vitality and promote plant resilience with our microbial blends, harnessing the power of diverse microorganisms to improve soil structure, nutrient availability, and disease suppression. View Collection Plant Protect Safeguard your crops naturally with our Plant Protection solutions, offering effective pest and disease management while minimizing environmental impact and preserving beneficial ecosystem balance. View Collection Crop Kits Simplify your farming experience with our comprehensive crop kits, including DATES PRO for organic growth elixirs, Insecta Repel for biological pest control, Rice Protect Kit for integrated pest and disease management, and BudMax Kit for optimized cannabis cultivation. Each kit is curated with everything you need for successful cultivation, empowering growers of all levels to achieve bountiful harvests with ease. View Collection Soil Conditioners Simplify your farming experience with our comprehensive crop kits. Each kit is curated with everything you need for successful cultivation, empowering growers of all levels to achieve bountiful harvests with ease. View Collection Contact us today to learn which microbial solution is best suited for your soil and crop needs. Contact us 1 2 3 ... 100 1 ... 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 ... 100

Pseudomonas stutzeri is a versatile bacterium essential in the nitrogen cycle, performing denitrification to convert nitrates into nitrogen gas, aiding in nitrogen balance and pollution reduction. Its ability to degrade hydrocarbons, pesticides, and heavy metals makes it a key player in bioremediation and wastewater treatment. Additionally, it supports sustainable agriculture through phosphate solubilization and plant growth promotion. Its adaptability and diverse metabolic capabilities position it as a valuable organism for environmental restoration and biotechnological applications. < Microbial Species Pseudomonas stutzeri Pseudomonas stutzeri is a versatile bacterium essential in the nitrogen cycle, performing denitrification to convert nitrates into nitrogen gas, aiding in nitrogen balance and pollution… Show More Strength 1 x 10⁹ CFU per gram / 1 x 10¹⁰ CFU per gram Product Enquiry Download Brochure Benefits Nitrogen Fixation Capable of fixing atmospheric nitrogen, enhancing soil fertility and supporting plant growth. Soil Health Improvement Contributes to nutrient cycling in soil, promoting overall soil health and ecosystem balance. Pollutant Degradation Effectively degrades a wide range of organic pollutants, aiding in environmental cleanup. Bioremediation Role Plays a crucial role in bioremediation processes, especially in the degradation of hydrocarbons and heavy metals. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Content coming soon! Mode of Action Content coming soon! Additional Info Contact us for more details Dosage & Application Contact us for more details FAQ Content coming soon! Related Products Saccharomyces cerevisiae Bacillus polymyxa Thiobacillus novellus Thiobacillus thiooxidans Alcaligenes denitrificans Bacillus licheniformis Bacillus macerans Citrobacter braakii More Products Resources Read all

Boost root growth with our Mycorrhiza Powder. Top-quality, 100% organic, and certified. Ideal for vibrant plants. Trusted by thousands of satisfied customers. < Root Enhancers Mycorrhiza Powder Enhances root growth and nutrient absorption for healthier plants and improved soil structure. Ideal for mixing into soil or applying to roots and seeds. Product Enquiry Download Brochure Benefits Stress Resistance and Improved Crop Quality Mycorrhizae help plants overcome stress conditions like drought, diseases, and nutrient deficiencies, enhancing crop quality and yield. Improved Phosphate Uptake and Mobilization Mycorrhizae enhance the uptake and mobilization of phosphate across all crops, reducing the need for phosphorus fertilization. Enhanced Root Growth and Development Mycorrhizae improve plant root growth and development by forming symbiotic relationships with roots, increasing surface area for better water and nutrient absorption. Enhanced Nutrient Absorption and Translocation Mycorrhizae facilitate the absorption and translocation of essential nutrients such as nitrogen, potassium, iron, and others, improving plant nutrient utilization efficiency. Benefits Dosage & Application How it works FAQ Additional Info Dosage & Application For best results, mix 5–10 g of Mycorrhizae Fertilizer into the planting hole or root zone at transplanting. For seed treatment, coat seeds with 2 g per kilogram before sowing. Reapply Mycorrhiza Powder every 8–12 weeks during active growth. Additional Info Ideal for a Wide Range of Crops Mycorrhiza Powder is beneficial for a diverse array of plant life, including: Cereals, Millets, Pulses, Oilseeds, Fibre Crops, Sugar Crops, Forage Crops, Plantation crops, Vegetables, Fruits, Spices, Flowers, Medicinal crops, Aromatic Crops, Orchards, and Ornamentals. Compatibility Our Mycorrhizae Fertilizer is compatible with organic and conventional farming systems. It contains multiple strains of endomycorrhizal fungi proven to thrive in diverse soil types. Safe for all plant species, from vegetables and ornamentals to trees and turf. Shelf Life Stable within 1 year from the date of manufacturing when stored in a cool, dry place away from direct sunlight. Packing We offer tailor-made packaging solutions to meet the specific requirements of our customers, ensuring the product reaches you in optimal condition. Benefits Using our Mycorrhiza Powder as a Mycorrhizae Fertilizer delivers multiple advantages: Accelerated root development for faster establishment. Improved nutrient uptake, especially phosphorus and micronutrients. Enhanced drought tolerance and disease resistance. Better soil structure through increased aggregation and aeration. How it works What Is Mycorrhizae Fertilizer and How Does It Work? Mycorrhizae Fertilizer is a symbiotic blend of beneficial fungi that colonize plant roots to improve water and nutrient absorption. When you apply our Mycorrhiza Powder, these fungi form an extensive hyphal network, effectively expanding the root system’s reach. As a natural Mycorrhizae Fertilizer, it enhances phosphorus uptake, stimulates root branching, and helps plants resist environmental stresses. FAQ What plants need mycorrhizal fungi? Most vegetable, fruit, and ornamental species benefit, especially legumes, cereals, and woody ornamentals. Mycorrhizae form symbioses with over 80% of terrestrial plants. Can you use too much mycorrhizal? Excessive mycorrhizal inoculant rarely harms plants, but ideal rates ensure cost-effective colonization. Over-application may be wasteful without added benefit. What are the benefits of mycorrhizal fungi? They improve nutrient and water uptake, enhance disease resistance, reduce transplant shock, and foster long-term soil health by creating a living rhizosphere. Related Products Mycorrhiza Liquid More Products Resources Read all