By Pundt, L. UConn Extension
2015 updated 2023
What are biological fungicides?
Biological fungicides (“biofungicides”) are composed of beneficial microorganisms including specialized fungi, bacteria and actinobacteria (filamentous bacteria). These microorganisms are often found naturally occurring in soils and are used to suppress fungi and bacteria that cause plant diseases. Researchers have isolated specific strains that have been formulated with additives to enhance their performance and storage.
Biological fungicides are living organisms that are best used preventively before disease occurs and not as rescue treatments for already diseased plants. They should always be combined with proper sanitation and other cultural practices that promote plant health.
How do biological fungicides work?
Biofungicides work (their mode of action) in several different ways including direct competition or exclusion, antibiosis, predation, or parasitism, induced resistance, and plant growth promotion. Many biological fungicides work in multiple ways, such as by competition and parasitism, so are less likely to develop resistance than conventional fungicides, particularly single-site fungicides with a specific mode of action.
Direct Competition/ Exclusion
Before root infection can occur, pathogens must gain accesses to the zone closely associated with the root, known as the
rhizosphere. For foliar diseases, the pathogen must contact the leaf or flower zone. The biofungicide grows a defensive barrier around this root, leaf, or flower zone. The beneficial microbes compete with plant pathogens for nutrients, infection sites and space, excluding the pathogen.
Antibiosis
The biofungicide produces chemical compounds or secondary metabolites such as antibiotics or other toxins that kill the target organism. The biofungicide create compounds that inhibit fungal or bacterial spores from germinating and causing plant disease, or the compounds restrict the pathogen’s growth.
Predation or parasitism
The biofungicide attacks and feeds on the pathogen, producing enzymes that degrade cell walls, inhibiting or killing the pathogen
Induce Resistance to the Host Plant
The biofungicide triggers the host plant to turn on its own defense mechanisms. Plants produce salicylic acid (a derivative of aspirin) which travels to other parts of the plant and signals these tissues to activate their natural defense mechanisms. This is known as systemic acquired resistance (SAR) or induced systemic resistance (ISR) improving the plants response to pathogen attack by priming the metabolism of plant defense compounds.
Plant Growth Promotion
The biofungicide promotes root and shoot growth in the absence of disease-causing plant pathogens. There may be increased nutrient availability of iron and other micronutrients by changing the pH or enzymes that help break down insoluble nutrients.
Some Common Beneficial Microorganisms that are Commercially Available
Beneficial fungi such as Trichoderma have been isolated from soil, decaying wood, and plant organic matter. Different species are commercially available including T. harzianum, T. virens, T. asperellum and T. gamsii. Dormant spores of Trichoderma are applied, the spores germinate and the fungal mycelia (Mycelium is the vegetative part of a fungus consisting of a mass of branching, thread-like hyphae) coils around plant roots blocking the pathogen, which results in a barrier to infection. The fungus also attacks the pathogen by secreting enzymes that attack the pathogen’s cell wall. There is also enhanced plant and root growth, so the fungus has more roots to colonize. The combination of T. harzianum and T. virens suppresses of Pythium aphanidermatum and has more benefit against Phytophthora than T. harzianum alone.
Gliocladium catenulaturm is a fungus isolated from Finnish field soil. It colonizes the leaf and root surface. Gliocladium works by hyperparasitism and competition for nutrients and space.
Bacteria
Bacillus subtilis is a naturally occurring saprophytic bacterium that induces systemic resistance. It forms a protective endospore that can survive extreme environmental conditions. There are different strains commercially available.
Bacillus subtilis works in several ways producing antibiotics, displacing the pathogen by inhibiting spore germination, and interfering with the attachment of the pathogen to the plant. It improves plant immunity and signals these tissues to activate their natural defense mechanisms.
When combating bacterial diseases, growers can alternate Bacillus with copper fungicides to help reduce the potential for plant damage or phytotoxicity that may occur from repeated sprays of some copper products. Bacillus can also be
used against fungal leaf spots. Bacillus amylolquefaciens colonizes the plant rhizosphere, stimulating plant growth and suppressing competing fungal and bacterial pathogens. Streptomyces is a filamentous bacterium found in soil and decaying vegetation that produces spores and antibiotics. Streptomycin takes its name directly from Streptomyces. Streptomyces K 61 was originally isolated from sphagnum peat and S. lydicus strain WYEC 108 is a naturally occurring bacterium found in the soil.
Benefits of Biological Fungicides
- Reduced risks to applicators and the environment.
- Shorter re-entry intervals and days to harvest intervals than many conventional fungicides.
- Many are labeled for use on edible crops including herbs and vegetable bedding plants.
- Most (but not all) are Organic Materials Review Institute (OMRI) approved for organic production.
- There may be less chance of plant damage, but not always, so consult product labels and company websites for plant safety precautions.
- Generally compatible with beneficial predators and parasites (natural enemies), beneficial nematodes (check company websites for more information).
- Improved uptake of certain nutrients.
- Can be used in rotation with conventional chemicals to reduce the risk of pathogens developing resistance to conventional fungicides (especially single-site systemic fungicides).
Limitations of Biological Fungicides
- Must be used preventively, for they will not cure diseased plants.
- Must be used with proper cultural controls for plant growth, including clean starter plant material and growing conditions.
- Must use strict sanitation protocols.
- Have a shorter shelf life (consult labels) than conventional fungicides and need to be stored under proper conditions to avoid mortality.
- May need to be re-applied more often than conventional fungicides.
How to Apply Biofungicides
You must start with clean greenhouses and clean plant material. Biological fungicides MUST be used as a preventive treatment. For foliar diseases, it may be helpful to combine their use with the selection of disease-resistant cultivars for disease suppression.
Apply immediately after mixing with water. Check company websites for compatibility information with other materials. Because biofungicides are living organisms, they have a limited shelf life and need to be stored under proper conditions. Do not stockpile biofungicides and be aware of the expiration date on their package. Most need to be stored under cool, dry conditions.
In University studies, researchers sometimes see an uneven effect when applying biological fungicides; however, these studies are conducted with higher disease pressures than in commercial greenhouses. To complete your own in-house trials, leave several plants untreated to serve as your control treatment. Differences in your crop, potting mix, media pH, fertilizer use and disease pressure may influence how well these different products work for you.
Biological fungicides are a useful tool for growers if they are used preventively, in combination with proper sanitation and other cultural practices.
Some Selected Biological Fungicides Used in Greenhouse Production
If any information is inconsistent with the label, then follow the label.
| Trade Name/ Re-Entry Interval (REI)/ Organic Product/ Manufacturer | Organism | Targets | Crops | Shelf Life |
| Actinovate SP 1 hr. REI OMRI-certified Product FRAC BM 02 Mycorrhizal applications | Streptomyces lydicus WYEC 108 | Soil Drench: Pythium, Rhizoctonia, Fusarium, Phytophthora. Foliar: Mildiú, Tizón de Botrytis, Xanthomonas | Greenhouse ornamentals | 1 year |
| BotryStop WP 4 hr. REI OMRI-certified product BioWorks | Ulocladium oudemansii U3 | Botrytis cinerea, Sclerotinia sclerotiorum | Greenhouse ornamentals, vegetables & fruits | 1 year (Refrigerated) Do not freeze. |
| CEASE 4 hr. REI OMRI-certified product FRAC BM 02 BioWorks | Bacillus subtilis QST 713 | Soil Drench: Rhizoctonia, Pythium, Fusarium, PhytophthoraAplicación Foliar spray: Anthracnose, Bacterial leaf spots, Botrytis Blight, Downy Mildew, Fungal Leaf Spots, Powdery Mildew, Rust, and others (see label for specifics) |
Greenhouse ornamentals, vegetables, herbs, fruits | 3 years (70-75° F) |
| Companion Biological Fungicide Wettable Powder 4 hr. REI OMRI-certified product FRAC BM 02 Douglas Plant Health |
Bacillus amyloliquefaciens ENV503 | Alternaria, Botrytis, Powdery mildew, Fusarium, Phytophthora, Pythium, Rhizoctonia, Xanthomonas | Greenhouse ornamentals, vegetables, and herbs | 2 years |
| EcoSwing REI 4 hr. Producto certificado por OMRI Gowan | Swinglea glutinosa extract | Alternaria Leaf spot, Basil Downy Mildew, Powdery Mildew | Greenhouse ornamentals, vegetables, herbs, fruits | 3 years |
| Howler 4 hr. REI OMRI- certified product FRAC BM 02 AgBiome | Pseudomonas chlororaphis AFS009 | Foliar diseases: Alternaria Leaf Spot, Anthracnose, Downy mildews, Botrytis, Powdery Mildews Root rots: Fusarium, Phytophthora, Pythium, Rhizoctonia |
Greenhouse Ornamentals | |
| LALSTOP G46 WG 4 hr. REI OMRI-certified product FRAC BM 02 Lallemand Plant Care | Clonostachys rosen J1446 (formerly Gliocladium catenulatum J1446) | Botrytis, Fusarium, Phytophthora, Pythium, Rhizoctonia, Powdery Mildew leaf spots & blights |
Greenhouse ornamentals, vegetables, herbs, fruits | 1 year |
| LALSTOP K61 WP 4 hr. REI OMRI-certified product FRAC BM 02 Lallemand Plant Care | Streptomyces K61 | Supression of Botrytis blight, Damping off, root rot diseases (Fusarium, Phytophthora, Pythium, Rhizoctonia) |
Greenhouse ornamentals, vegetables, and herbs | 1 year |
| Obtego 4 hr. REI OMRI-certified product FRAC BM 02 SePro | Trichoderma asperellum ICC 012 and Trichoderma gamsii ICC 080 | Fusarium, Phytophthora, Pythium, Rhizoctonia, Sclerotinia, Thielaviopsis and others |
Greenhouse ornamentals, vegetables, herbs, fruits | 15 months |
| Regalia GC 4 hr. REI OMRI-certified product FRAC P05 ProFarm | Reynoutria sachalinensis extract | Anthracnose, Bacterial Leaf Spots, Botrytis Blight, Downy Mildew, Fungal Leaf Spots, Late Blight, Powdery Mildew |
Greenhouse ornamentals, vegetables herbs, fruits | 3 years |
| RootShield Granules 4 hr. REI OMRI-certified product FRAC BM 02 BioWorks | Trichoderma harzianum Rifai T-22 |
Root rot diseases: Pythium, Rhizoctonia, Fusarium, Cylindrocladium, Thielaviopsis | Greenhouse ornamentals, some vegetables, herbs, fruits | 10 months (Refrigerated) |
| RootShield WP 4 hr. REI OMRI-certified product FRAC BM 02 BioWorks | Trichoderma harizanum Rifai T-22 | Root rot diseases: Pythium, Rhizoctonia, Fusarium, Cylindrocladium, Thielaviopsis |
Greenhouse ornamentals, vegetables, herbs, fruits. | 10 months (Refrigerated) |
| RootShield Plus WP 4 hr. REI OMRI-certified product FRAC BM 02 BioEorks |
Trichoderma harzianum Rifai T-22 and Trichoderma virens G-41 | Root rot diseases: Pythium, Phytophthora, Rhizoctonia, Fusarium, Cylindrocladium, Thielaviopsis | Greenhouse ornamentals, vegetables, herbs | 10 months (Refrigerated) |
| RootShield Plus WP 4 hr. REI OMRI-certified product FRAC BM 02 BioEorks |
Trichoderma harzianum Rifai T-22 and Trichoderma virens G-41 | Root rot diseases: Pythium, Phytophthora, Rhizoctonia, Fusarium, Cylindrocladium, Thielaviopsis, Sclerotina | Greenhouse ornamentals, vegetables, herbs, fruits | 10 months Refrigerated |
| Soilgard 4 hr. REI OMRI-certified product Certis USA | Gliocladium virens GL-21 |
Root and crown rots (Pythium, Rhizoctonia, Sclerotina, Phytophthora, Sclerotium and Fusarium) | Greenhouse ornamentals and vegetables | 1 year (If opened will keep 3 months if refrigerated (40°F to 45°F)) |
| Triathlon BA 4 hr. REI OMRI-certified product FRAC BM 02 OHP | Bacillus amyloliquefaciens D747 | Damping off (Pythium, Phytophthora, Rhizoctonia, Fusarium), Bacterial & Fungal Leaf Spots, Downy Mildew, Powdery Mildews, Botrytis blight, Rust (depending upon crop, see label) | Greenhouse ornamentals, vegetables, herbs, fruits | 1 year |
This information is supplied with the understanding that no discrimination is intended and no endorsement implied. Due to constantly changing regulations, we assume no liability for suggestions. If any information in these tables is inconsistent with the label, follow the label. Always follow label instructions regarding registered uses and note cautions. Not all diseases are labeled for all crops. To avoid any phytotoxicity problems, spot test first before widespread use.
Biological fungicides are regulated by the EPA and have an EPA registration number, whereas microbial inoculants do not. Some of the active ingredients in biological fungicides may also be sold as microbial inoculants.
Disclaimer for Fact Sheets: The information in this document is for educational purposes only. The recommendations contained are based on the best available knowledge at the time of publication. Any reference to commercial products, trade or brand names is for information only, and no endorsement or approval is intended. UConn Extension does not guarantee or warrant the standard of any product referenced or imply approval of the product to the exclusion of others which also may be available. The University of Connecticut, UConn Extension, College of Agriculture, Health and Natural Resources is an equal opportunity program provider and employer.
Resources
- Bioworks Product Shelf Life https://bioworksinc.com/wp-content/uploads/products/shared/productshelf-life.pdf (accessed July 2023)
- Caldwell, B, E. Sideman, A. Seaman, A. Shelton, and C, Smart. 2013. Resource Guide for Organic Insect and Disease Management. 2nd edition. Cornell University. (New York State Agricultural Experiment Station). 150 pp. https://www.sare.org/wp-content/uploads/Resource-Guide-for-OrganicInsect-and-Disease-Management.pdf
- Chase, A. R. 2013. Biological Update. Greenhouse Management. April 2013.
- Daughtrey. M. 2015. Fundamentals of Biological Controls of Fungal and Bacterial Diseases. E-Gro Biocontrol webinar http://e-gro.org/webinars.php
- Dicklow, M. B. 2014. Biofungicides. UMass Extension Fact sheet. Updated 2018. https://ag.umass.edu/fact-sheets/biofungicides
- Elmer, W. H. 2008. Biological and Biorational fungicides offer control options. NM Pro. August 2008. 63-66.
- Harman, G. E. 2006. Overview of Mechanisms and Uses of Trichoderma spp. Phytopathology. 96:190-194
- Raudales, R., and C. McGehee. 2017. Biofungicides for Control of Root Diseases on Greenhouse-Grown Vegetables. EGro Edible Alert. 2(7): April 2017