Nematodes are microscopic roundworms that feed on plant roots and can cause major damage to alfalfa crops. Infestations lead to stunted, weak plants with reduced yields. Severe cases can even kill plants. There are several methods to control nematodes organically and conventionally, but prevention and early intervention are key.
Understanding Nematodes
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Nematodes are non-segmented roundworms residing in soil that feed on plant roots.
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Major alfalfa pests include root-knot stem stubby-root, and lesion nematodes.
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Feeding prevents nutrient and water uptake, causing plants to wilt, yellow, and have poor growth.
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They reproduce rapidly, quickly escalating from low to extremely high populations.
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Typical signs are stunted, chlorotic plants with poor root systems. Plants decline and die under heavy pressure.
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Confirm nematode damage by submitting soil and root samples to diagnostic labs for analysis.
Cultural Practices for Prevention
Cultural methods like crop rotation, sanitation, and soil solarization help reduce nematode populations without chemicals:
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Rotate with non-host crops like corn, grains, cotton, or soybeans for 2-4 years to lower nematode levels.
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Eliminate weeds and old crop debris that can harbor nematodes. Keep fields bare with tillage.
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Solarize soil under clear plastic in summer to kill nematodes and other pests with heat.
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Plant cover crops like mustard, radish, and sorghum which suppress nematodes as organic biofumigants.
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Use compost with microbial activity antagonistic to nematodes. Well-aged, hot compost devitalizes nematodes.
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Allow fields to dry out and crack deeply between crops. Nematodes need soil moisture to move and infect.
Resistant Alfalfa Varieties
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Planting nematode-resistant alfalfa varieties avoids damage without pesticides. Consult local extension office for recommendations.
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Resistant cultivars like Moapa, Lahontan, and Ranger have genetic traits that deter nematode feeding and reproduction.
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Introduce novel resistant varieties periodically as pests can adapt and overcome resistance over time.
Biological Control Agents
Natural biological agents can be introduced to reduce nematode populations:
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Predatory fungi like Arthrobotrys attach to and digest nematodes in soil.
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Beneficial nematodes prey on pest nematodes without harming plants. Seek expert guidance before release.
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Antagonistic cover crops like sorghum and marigolds suppress nematodes through biochemicals.
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Compost teas containing beneficial microbes combat nematodes when used as soil drenches.
Chemical Nematicides
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Chemical nematicides should be a last resort for only severe infestations after trying other methods.
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Non-fumigant nematicides include organophosphates, carbamates, and avermectins. Follow label precautions carefully.
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Fumigants like metam sodium kill all organisms in treated areas. They require specialized protective equipment to apply. Avoid if possible.
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Always rotate chemical modes of action annually to prevent resistance. Combine with cultural tactics for most effective control.
Key Preventive Measures
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Scout fields routinely and submit samples for analysis if nematode damage is suspected.
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Sanitize farm equipment thoroughly before entering clean fields.
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Use nematode-free seed and transplants to avoid introducing pests.
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Weed early and often – many common weeds host nematodes.
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Allow soil to dry and crack deeply between croppings.
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Rotate with non-susceptible crops for extended periods.
Post-Harvest Nematode Management
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Plow under crop debris immediately after harvest to speed decomposition of infected material.
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Leave fields fallow for a full season. Avoid successive alfalfa plantings.
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Apply compost, manure, or other organic matter to improve soil health and microbial activity.
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Follow crop rotation schedule rigorously. Do not plant alfalfa again for minimum 2-4 years.
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Monitor nematode levels with periodic soil sampling. Only re-plant alfalfa when populations are low.
Nematode Species Damaging Alfalfa
Four major nematode pests target alfalfa roots:
Root-Knot Nematodes
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Most widespread and destructive nematode on alfalfa and many other crops.
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Feed on roots causing galls, lesions, rotting. Above-ground symptoms are stunted, wilt.
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Persist in soil for years. Survive hot, dry conditions. Wide host range.
Stem and Bulb Nematodes
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Attack root tips, crowns, bulbs. Cause swollen areas on roots and lower stems.
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Salinity tolerance allows survival in alkaline soils.
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Feeding stops root elongation leading to stubby, branched roots. Plants are stunted.
Stubby-Root Nematodes
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Feeding inhibits root elongation, causing short, swollen roots with few lateral roots.
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Leads to nutrient deficiencies. Plants are stunted and unthrifty.
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Survive in protected root debris. Common in Western states.
Lesion Nematodes
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Feed inside root tissue, causing lesions that coalesce and girdle roots as they expand.
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Rotting roots cannot take up nutrients and water. Plants wilt on hot days.
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Cause significant yield loss. Most prevalent in warmer climates.
Signs of Nematode Damage
Watch for these symptoms signaling thrifty, declining alfalfa:
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Stunted, yellowed, wilted plants despite adequate moisture.
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Plants in patches of poor growth. Lower yields.
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Roots with swellings, galls, lesions, rotting. Few fine feeder roots.
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Nutrient deficiencies – nitrogen, phosphorus, potassium.
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Cracked, dry soil allows deep penetration to roots.
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Weeds indicative of root stress like nutsedge, purslane, spurge.
Scouting for Nematodes
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Sample soil and roots when symptoms appear or prior to planting new fields.
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Collect multiple sub-samples, mix, and submit about 1 pint of soil to a diagnostic lab.
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Sample again 30-60 days after initial test to gauge population changes.
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Keep detailed records of cropping history, nematode levels, and control efforts.
How Nematodes Damage Alfalfa
Nematodes inflict damage through:
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Piercing and sucking cell contents with needle-like feeding stylets.
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Injecting salivary secretions that break down plant tissue and cells.
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Transmitting debilitating plant viruses as they feed and move between plants.
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Destroying root systems leading to poor nutrient and water uptake.
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Disrupting plant growth hormones like cytokinins.
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Triggering competitive saprophytic organisms that attack weakened roots.
Crops for Alfalfa Rotation
Rotate alfalfa with these non-susceptible crops to reduce nematodes:
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Small grains like wheat, barley, oats, and rye starve nematodes. Leave 2+ years.
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Corn breaks pest cycles. Rotate 3-4 years until nematodes decline.
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Soybeans are poor nematode hosts. Rotate at least 2 years.
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Sorghum exudes nematicidal compounds from roots. Rotate 2+ years.
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Cotton reduces root-knot nematodes. Leave fields fallow after harvest.
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Clovers help disrupt nematode life cycles when rotated with alfalfa.
Solarizing Soil to Kill Nematodes
Solarization uses the sun’s heat to pasteurize soil:
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Mow, irrigate, and till field to seedbed smoothness 2-3 weeks before solarizing
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Spread transparent polyethylene plastic flat over moist soil from early summer through mid-fall.
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Weight edges and seams with soil to prevent airflow under plastic.
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Maintain plastic integrity if tearing occurs. Repair immediately.
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Temperatures up to 140°F kill nematodes, weeds, disease agents.
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The deeper heat penetrates, the more effective control. Solarize 6 weeks minimum.
Using Organic Biofumigants
Biofumigants release natural nematotoxic compounds:
Mustard Greens
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Plant densely in fall and incorporate green matter into soil 2-3 weeks later.
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Biofumigants break down quickly so till under rapidly after chopping.
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Use lower rates around direct-seeded crops and higher rates for nurseries and transplants.
Oilseed Radish
- Provides both biofumigation an
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Alfalfa Stem Nematode (ASN) is a nearly microscopic round worm that enters the alfalfa plant and lives in the stems and leaves, usually above ground. Under ideal conditions (wet weather in late winter or early spring, at 59-70°F), ASN can complete its life cycle from egg to reproducing adult in 19-23 days. A single ASN female, after mating with a male, can produce 200-500 eggs during its reproductive life. ASN can parasitize and persist on a number of host plant species, but can only reproduce in alfalfa and sainfoin. ASN can undergo anhydrobiosis, a state of drying to near death, and persist in plant debris, on seeds, or in dry soil for a very long time.
A lfalfa stem nematode, Ditylenchus dipsaci, belongs to a diverse species of nematode often referred to as stem and bulb nematodes. Within this species are a number of races or strains of the nematode. Alfalfa Stem Nematode is one that attacks and reproduces only on alfalfa (Medicago sativa) and sainfoin (Onobrychis viciifolia) plants. The ASN occurs in all regions of alfalfa production worldwide and can dramatically reduce plant stand and forage yields. Several nematodes are known to parasitize alfalfa; however, ASN is the most serious nematode causing damage in alfalfa production.
ASN is increasingly a concern to alfalfa producers in all regions of Utah; however, noticeable losses have occurred in Millard, Cache, and Box Elder counties. Symptoms are easily recognized in the early spring during cool wet weather. Damage is most often seen in flood-irrigated fields with increased damage observed near the headwater ends of infected fields. Newly established alfalfa on ASN infested ground often declines rapidly with poor seedling stand, increased weed pressure, and poor forage yield. Alfalfa production with moderate to severe ASN pressure (Fig. 1) rapidly becomes unprofitable within a year or two after planting.
Infected plants tend to be stunted with very small “mouse eared” leaves. Infected stems have shortened internodes and swollen nodes (Fig. 2). Under the right climatic conditions, infected plants can appear yellow (Fig. 3) or even white in color (often called white flagging). This symptom is readily observed at green-up in the early spring or just after the first cutting. However, chlorotic flagging may be an indicator of other problems and alone does not indicate the presence of the ASN. Crinkled leaves are often observed on infected plants, with crinkling occurring between veins, not crossing them. Infected stems are brittle and tend to break off from the crown. Crowns of infected plants are not firm and may even appear spongy in consistency. Infected areas of the field are about 2-3 weeks slower to green-up in the spring compared to noninfected areas and appear to have winter killed. Although plants persist with moderate ASN pressure, eventually, with increasing ASN populations, they will die and plant stands will become patchy with blank spaces. Stand decline will increase weed pressure.
All species of plant parasitic nematodes have a hollow stylet that is used to puncture the plant’s cells so that they can feed on the plant cellular contents. ASN also has this trait (Fig. 4), but is among a small number of nematode species that can live and complete its life cycle, most often, above ground free of soil contact. ASN progresses through several life stages beginning with the egg. Within the egg, the nematode develops and goes through its first molt. After egg-hatch, the nematode goes through two additional molts to become a pre-adult or infective juvenile. At this stage the nematode can withstand extremes of freezing and drying for long periods by persisting in or on the surface of hay or plant debris and/or seed (Figs. 5 and 6), or in the crowns of plants when survival conditions are adverse. When there is sufficient moisture and favorable temperatures, the infective juveniles become active, enter the plant by colonizing seedlings as they germinate or by swimming up on the surface and entering through the plant’s stomates. The nematodes are small enough to move within the plant’s internal open spaces between cells. The nematodes secrete enzymes and plant-affecting hormones as they feed that stunt and swell plant tissues. Within the host plant, the nematodes molt a fourth time to become male and female adults. After mating, females can lay 200-500 eggs during their life. A complete life cycle, from egg to egg-laying adult, is 19-23 days at 59-70 F air temperature. Nematodes escape to the soil when living conditions within the plant become adverse when heavily infected plants can no longer support the nematode’s growing population, or when plants are dying. Pre-adult juveniles can survive in/on plant debris or seed under dry conditions for years (Figs. 5 and 6).
To verify that ASN is causing the symptoms in alfalfa, stems and leaves of symptomatic plants can be sampled and checked for the nematodes. Your local county Extension educator may be able to do this for you as they often can provide diagnoses quickly and accurately with the aid of a microscope. If confirmation is desired, then the sample may be sent to the diagnostic laboratory. To do this collect stems with leaves from several plants exhibiting symptoms of infection. Plant tissues should be sealed in a plastic bag and sent to the: Utah Plant Pest Diagnostic Lab, Department of Biology, 5305 Old Main Hill, Logan UT 84322-5349. Care should be taken not to expose the bag to excessive heat or cold so that the specimen and nematodes remain alive until the sample is received. General instructions for sample collection and shipment can be found at: http://utahpests.usu.edu/uppdl/htm/ forms and directing your browser to the diagnostic laboratory sample submission information.
Chemical nematicides for controlling ASN are generally ineffective, hazardous, and expensive. Some insecticides are labeled for control of ASN, but studies have shown their efficacy is marginal under ideal conditions at their labeled rates for nematode control. The decision to turn under a field should be based on plant stand and current forage yields rather than nematode population numbers. A comprehensive integrated approach is the best strategy for controlling ASN. Following are recommendations that, if implemented, will reduce the impact of ASN on alfalfa production.
Crop rotation is one of the most effective means to control ASN. Planting non-host crops such as small grains (barley or wheat, avoid planting oats), sorghum, or corn for two or more years will reduce stem nematode populations. Longer rotations work better. Special attention should be taken to eliminate volunteer alfalfa during the rotation period, as nematodes will carry over on these plants.
Plant varieties of alfalfa that are resistant to the alfalfa stem nematode, preferably certified seed that carries the official label indicating it is certified. Several varieties are listed as being resistant to the nematode, but measures of resistance can differ. Some companies consider a variety resistant when only 51% of plants test negative for the presence of the nematode under screening trials. Theoretically, this could mean that nearly half the plants will have ASN. Eventually the ASN will overcome resistant plantings and rotation to non-host crops will likely be required. Avoid planting “brown bag” seed (non-certified) that is claimed to be resistant to ASN. It is an unnecessary risk and there are no assurances of seed purity, germination percentage, and the seed may already be contaminated with the nematode (see Fig. 6). No seed certification laboratory, to our knowledge, tests for the presence of the nematode in or on their seed, but certified seed is guaranteed for varietal purity and germination and is sold on that basis. Variety recommendations can be obtained from your local county Extension educator.
Pr event nematode reintroduction into a clean field by taking these precautions: cut new clean fields first, be sure the topsoil is dry, do not cut the alfalfa when the top 2-3 inches of soil surface is wet as nematodes will exit the plants and return to the soil once they sense the plant is dying; clean equipment before moving from one field to another; avoid using tail water from a known ASN contaminated field; avoid the temptation to plant “brown bag” seed with claims of pedigree purity and resistance to ASN; avoid the use of manure from cattle operations, where infected hay is used as feed, to spread on rotation crops or new alfalfa plantings as a fertilizer. These recommended “ounces of prevention” are potentially worth tons of forage.
- Agrios, G. N. 1997. Plant Pathology, 4th ed. Academic Press, San Diego, CA. pp. 635.
- Summers, C.G. 1998. Integrated Pest Management in Forage Alfalfa. Integrated Pest Management Reviews 3(3):127-154.
- Thorne, G. 1961. Principles of Nematology. McGraw-Hill Book Company, Inc., New York, NY. pp. 553.
Published January 2008 Utah State University Extension Peer-reviewed fact sheet
Kent Evans, Extension Plant Pathology Specialist; Clark Israelsen*, Cache County; Mike Pace*, Box Elder County *Utah State University County Extension Agents
Extension Professor | Horticulture & Agronomy | Box Elder County Director
Agriculture and Natural Resources Phone: (435) 695-2541 Email:
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Nematodes in Alfalfa with W-L Alfalfa
FAQ
What kills nematodes instantly?
What to plant to get rid of nematodes?
What is a home remedy for nematodes?
What nematodes eat alfalfa?
Plant-parasitic nematodes are microscopic thread-like worms that live in soil and plant tissues and feed on plants by puncturing and sucking the cell contents with a needlelike mouthpart called a stylet. The alfalfa stem nematode feeds in the stems and crowns of the alfalfa plant, while the other nematodes listed above feed on roots.
How do you control alfalfa nematodes?
Consequently, rotation with nonhost crops such as tomatoes, small grains, beans, and corn on a 2- to 4-year basis should reduce alfalfa stem nematode numbers (longer is better for heavily infested fields). Control volunteer alfalfa plants in subsequent crop rotations.
Can a root lesion nematode kill alfalfa?
Secondary infections of roots by bacterial and fungal pathogens commonly occur with a root lesion nematode infestation; feeding by root lesion nematodes may overcome the resistance of the alfalfa varieties to these pathogens. Damage caused by lesion nematode depends on the alfalfa variety and the species of lesion nematode present in the field.
Are nematodes cost effective for alfalfa production?
Nematicides are not cost effective for alfalfa production. If lesion nematodes are present in the field, it is important to maintain good plant health. Plants that are stressed (for example from too little water) will be more susceptible to lesion nematode damage.