Pathogen
Lesion nematodes belong to the genus Pratylenchus and are soilborne, plant-parasitic roundworms that may cause damage in corn. Individual lesion nematodes range between 0.3 to 0.9 millimeters (0.01 to 0.03 inches) long and thus cannot be seen with the naked eye. These nematodes are known for their broad host-range and are capable of parasitizing over 400 crop plant species worldwide. The most common species found in corn production in North Carolina include P. brachyurus, P. penetrans, P. scribneri and P. zeae.
Lesion nematodes primarily feed on roots, rhizomes, tubers, and other underground plant structures. They feed by lysing, or breaking open, cells of the roots forming cavities and disrupting the function of the root. Necrotic lesions (spots of dead tissue, appearing dark in color) can be observed on the root because of the damage caused by feeding and movement. The feeding damage caused by nematodes can also become an infection point for other pathogenic soil microbes, such as fungi.
Figure 1. A lesion nematode female, of the species Pratylenchus penetrans.
A. Gorny, NC State University
Signs and Symptoms
Detecting lesion nematodes in corn may be difficult because symptoms observed above ground often resemble nutrient deficiencies and/or drought stress. When nematode populations are low, symptoms may not be present above ground. When nematode populations are high, aboveground symptoms include stunted or uneven plant growth, leaf chlorosis or yellowing, and small ears/kernels.
Characteristic root symptoms of lesion nematodes include swollen roots, lack of root branching/fine roots, stunted roots, and reddish-brown/black lesions along the roots. These lesions may appear in small, discrete spots at early stages of infection. As nematode feeding continues, lesions can coalesce and become larger, extended areas of necrotic lesions.
Diagnosis
If a corn crop is suspected to be suffering from lesion nematodes, plants should be dug up, taking care to preserve as much of the root system as possible. Roots can be washed gently in a bucket of water or under running water to remove soil. A visual inspection should include checking the plant roots for black necrotic lesions. However, this will not indicate the level of nematode pressure (nematode population counts) in the field. Diagnosis can be confirmed through assessment of soil and root samples for the presence of the nematode by a plant disease diagnostic laboratory or nematode assay laboratory. Soil samples for nematode assay services may be submitted to the North Carolina Department of Agriculture & Consumer Services, Agronomic Services (NCDA&CS), Nematode Assay Laboratory, 4300 Reedy Creek Road, Raleigh, NC 27607.
In order to determine nematode pressure, soil samples should be taken from several areas in the affected field. Using a soil probe, collect 20 to 30 soil cores across a 5 acre block, at a depth of 6 to 8 inches from each area using a grid-like or “zig-zag” pattern across the area. Combine soil cores in a clean plastic bucket and remove a smaller portion of soil from this larger sample to submit to the Nematode Assay Laboratory. Detailed sampling instructions can be found at the NCDA&CS Nematode Assay Laboratory sampling guidelines.
Disease Cycle
Lesion nematodes are obligate biotrophs, meaning they require living plant roots to feed and reproduce. Lesion nematodes are migratory endoparasites, meaning they migrate through roots even at the adult stage and retain a worm-like appearance throughout their life cycle. They can move through the soil, but mainly move and feed within plant roots.
The life cycle of the lesion nematode consists of six life stages: egg, four juvenile states and the adult stage. The life cycle typically takes 4 to 8 weeks to complete, but this generation time may be influenced by soil moisture, soil temperature, and host crop suitability. Female nematodes lay eggs one at a time in plant roots or soil, which develop to first-stage juveniles, then to second-stage juveniles before hatching from the egg. The second-stage juvenile nematodes can penetrate plant roots to feed and continue developing through a third- and fourth-stage, and finally into adults. Adult lesion nematodes may exit and re-enter the roots. Under favorable environmental conditions (presence of a suitable host crop, sufficient soil moisture, and favorable temperatures) lesion nematode populations can increase to over 1,000 nematodes per gram of root. Lesion nematodes can overwinter in infected root tissue, weed hosts, or in the soil at any life stage.
Management
Managing lesion nematodes can be difficult due to their broad host range (Table 1) and lack of corn varieties with genetic resistance to this pathogen. Routine soil sampling for nematode analysis is important to understand if a field has lesion nematode and monitor population counts. Knowledge of specific Pratylenchus species present in the field is helpful for determining if there is a non-host crop that can be integrated into the crop rotation. However, this information may be difficult to obtain, as it requires a detailed examination of the nematode specimen or a DNA-based test. Many species of lesion nematode can also infect, reproduce, and survive on common weeds. Therefore, good weed management will eliminate a potential food source for these nematodes.
| Pratylenchus species | Host Crops | Non-Host Crops |
| P. brachyurus | common bean, corn, cotton, cucurbit crops, okra, peach, peanut, soybeans, sweetpotato, tobacco, tomato, triticale cover crops | cabbage, lettuce and onion |
| P. penetrans | alfalfa, Bermuda grass, boxwood, corn, cotton, peach, red clover cover crops, rye, soybeans, sweetpotato, tobacco, tomato, white potato | perennial ryegrass and Sudan grass |
| P. scribneri | cole crops, common bean, corn, cotton, onion, peach, soybeans, tobacco, tomato, wheat | alfalfa |
| P. zeae | cole crops, corn, oats, okra, peach, sorghum, soybeans, sugarcane, tall fescue, tobacco, wheat | peanut, tobacco and tomato |
Two effective management tactics for lesion nematodes are sanitation procedures and the application of chemical nematicides. Avoiding the introduction of lesion nematodes into the field through sanitation procedures is highly beneficial, as they can be extremely difficult to get rid of once populations are established in the field. Careful sanitation by cleaning of equipment moved between fields is an effective way of reducing the spread of lesion nematodes between fields and farms. Sanitize by washing with a solution of 10% household bleach, removing any stuck soil, then rinsing with clean water and drying before moving to unaffected fields or areas.
Another effective management tactic to reduce lesion nematode populations within the field is the use of nematicides when economically viable. Pre-plant soil fumigation, at-plant non-fumigant nematicides or seed treatments, can reduce lesion nematode population levels to below economic thresholds. Chemical nematicide treatments are summarized in Table 2 and additional information may be found in the North Carolina Agricultural Chemicals Manual.
| Active ingredient and formulation | Amount | Notes |
|---|---|---|
| terbufos (Counter 20 G) | 5.0 lb/ac | Apply in furrow. Do not exceed 6.5 lb/ac of Counter 20 G |
| ethoprop (Mocap 15 G) | Consult label | Apply 3 days before planting or at-plant |
| abamectin (Avicta) | 0.15 mg per seed | Seed treatment |
| clothianidin 40.3% + Bacillus firmus I-1582 8.1% (Poncho/Votivo) | 0.25 to 0.50 mg per seed | Seed treatment |
| Bacillus amyloliquefaciens strain PTA-4838 16.5% (Aveo EZ) | 0.1 fl oz per 80,000 seed | Seed treatment |
| Heat-killed Burkholderia spp. strain A396 94.46% (BioST) | 8 oz per 100 lb seed | Seed treatment |
Additional Resources
The NCDA&CS Nematode Assay Lab provides soil detection and diagnostics.
The NCSU Plant Disease and Insect Clinic provides diagnostic and control recommendations.
The NC State Extension Plant Pathology portal provides information on crop disease management.
The Southeastern US Vegetable Crop Handbook provides information on vegetable disease management.
The North Carolina Agricultural Chemicals Manual provides an up-to-date list of chemicals available for control of nematodes and other diseases and pests.
Acknowledgements
This factsheet was prepared by the NCSU Plant Nematology Lab in 2021.
Publication date: Aug. 18, 2021
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