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Management of Plant-Parasitic Nematodes in Florida Peanut Production1

Zane J. Grabau and Donald W. Dickson 2

Nematodes in Peanut Production

Nematodes are non-segmented roundworms that are generally microscopic. They live in animal hosts, soil, plant roots, or water. Nematodes in agricultural systems usually live in soil and can be divided into three categories: (1) entomopathogenic nematodes that feed on insects; (2) free-living nematodes that feed on bacteria, fungi, or other nematodes and may be beneficial for crop production; and (3) plant-parasitic nematodes that feed only on plants and may drastically suppress yields on many crops, including peanut. This article is a guide to managing plant-parasitic nematodes in peanut production and is intended for use by agricultural professionals involved in the peanut industry through production, processing, advising, research, or regulation.

Some of the more virulent plant-parasitic nematodes of peanut reduce yield by decreasing root size and efficiency, leading to shorter shoots. Infected plants are generally stunted with varying degrees of yellowing (chlorosis). They produce fewer pegs and pods, and, in severe cases, die. Severe nematode infection, sometimes in combination with secondary infection by fungal pathogens, may also rot pods. The amount of damage nematodes cause is related to their population densities; the higher their density, the greater the damage.

Nematode population densities can increase rapidly in the field. Most plant-parasitic nematodes of peanut complete their life cycle (egg, four pre-adult juvenile stages, egg-producing adult) in three to four weeks depending on the nematode species and environmental conditions. On peanut, which is an approximately 135-day crop, nematodes may go through six or more generations in a single growing season. A mature female nematode can produce upwards of several hundred eggs, depending on the species of nematode and environmental conditions.

A basic understanding of the biology and types of plant-parasitic nematodes is helpful for making inform decisions on nematode management. Plant-parasitic nematodes of peanut spend their entire lives in soil or roots and can be sorted by where they reside when feeding, a fact that is important to remember when sampling for nematodes. Ectoparasites (ecto means outside) spend their entire lives outside the roots. Only the head end or stylet of an ectoparasite enters the roots when feeding (Figure 1). (A stylet is a needle-like mouthpart that all plant-parasitic nematodes possess.) Endoparasites (endo means inside) enter the root as a juvenile or adult and remain in the root to feed. Some endoparasites are migratory, which means they move while feeding. Other nematodes are sedentary, which means that they do not move once they begin feeding. A portion of the population of endoparasitic nematodes can be found in the soil at any given time because eggs generally hatch in the soil and mobile nematode stages may move freely in soil or from root to root.

 

Figure 1. An ectoparasitic nematode (sting nematode) feeding from outside roots.
Figure 1.  An ectoparasitic nematode (sting nematode) feeding from outside roots.
Credit: Ole Becker, University of California, Riverside; used by permission

 

Among plant-parasitic nematodes in Florida, root-knot nematodes (Figures 2 and 3), which are sedentary endoparasites, cause the most yield suppression to peanut because they are common and have high damage potential. Peanut root-knot nematode (Meloidogyne arenaria) and Javanese root-knot nematode (Meloidogyne javanica) both damage peanut in Florida, although the former is more common. There are many species or types of root-knot nematodes, and it is important to distinguish between these types because the different types infect different crops. Some species are also divided into different races based on the hosts they infect; however they are visually similar if not identical. For example, race 1 of the peanut root-knot nematode infects peanut, but race 2 does not; races 3 and 4 of the Javanese root-knot nematode infect peanut, but races 1 and 2 do not.

 

Figure 2. Mature female root-knot nematode removed from root.
Figure 2.  Mature female root-knot nematode removed from root.
Credit: Charles Overstreet, Louisiana State University; used by permission

 

 

Figure 3. Second-stage juvenile (J2) root-knot nematode under high magnification. This is the stage that emerges from eggs and enters the root to establish a feeding site.
Figure 3.  Second-stage juvenile (J2) root-knot nematode under high magnification. This is the stage that emerges from eggs and enters the root to establish a feeding site.
Credit: Zane Grabau, UF/IFAS

 

Lesion nematode (Pratylenchus brachyurus, Figure 4), a migratory endoparasite, is widespread, but is only mod­erately damaging. Peanut ring nematode (Mesocrionema ornatum), an ectoparasite, commonly infects peanut but has low damage potential. Sting nematode (Belonolaimus longicaudatus, Figure 5), an ectoparasite, can cause serious damage to peanut when present. Sting nematode is prob­ably not widespread in peanut production regions because it only occurs in sandy soils (80% or greater sand, 10% or less clay) with minimal organic matter. Root-knot and lesion nematodes that affect peanut can infest a wide range of soil types, although they tend to thrive in sandier soils. See the UF/IFAS publication on sting nematode for more information about this nematode.

 

Figure 4. Female lesion nematode under high magnification.
Figure 4.  Female lesion nematode under high magnification.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 5. Sting nematode females (F), males (M), and juveniles (J) under high magnification.
Figure 5.  Sting nematode females (F), males (M), and juveniles (J) under high magnification.
Credit: William Crow, UF/IFAS

 

Diagnostic and Advisory Services

Determining what nematodes are present in a field and at what densities is helpful for developing a plan for manag­ing nematodes. This can be accomplished by submitting soil, root, or pod samples to a professional nematology diagnostic lab, such as the UF/IFAS Nematode Assay Laboratory. These samples may be submitted to aid with the diagnosis of disease problems or for advisory service to predict whether or not a potential nematode problem may exist for a future crop. This information allows growers the opportunity to implement management practices to reduce the damage that nematodes may cause.

Detailed information about sampling for nematodes can be found at the UF/IFAS nematode assay laboratory website. When submitting samples for nematode diagnosis, either soil or soil-and-plant-root samples should be included. Always collect soil because ectoparasitic nematodes can only be recovered from the soil, and at least one stage of all endoparasites can be found in soil. It can be useful to collect plant roots in addition to soil when diagnosing crop damage. If the problem is caused by an endoparasitic nematode, then some nematodes will be found inside the roots. It is also helpful to submit pictures of roots and foliar to better illustrate any symptoms that may be present.

Soil samples for nematodes should be taken to about 12 inches deep. If plants or remnants of plants are still in the field, soil samples should be taken within a few inches of plant stems and should intersect plant roots if possible. Because nematode densities vary considerably across a field, about 20 soil cores of about an inch in diameter should be taken from an area of 10 acres or less. Thoroughly mix cores collected within a single area, and submit a 1-pint portion of this mixture for analysis. For larger areas, take multiple, separate samples, making sure to properly label them. Do not take samples when soil is excessively wet or dry. Store soil samples in closed plastic bags to protect them from drying and keep them cool, but not frozen, until shipment. Do not add water. When digging root samples, be sure to retain the soil surrounding the roots to slow decay by microbes. The collection and storage process for root samples is the same as the process for soil samples. If you intend to diagnose a problem with the current crop, it may be useful to collect separate samples from the symptomatic area and a healthy area for comparison.

While samples can be taken at any time, nematode populations fluctuate throughout the year, so timing can be important. In most cases, nematode population densi­ties peak around harvest while plant roots are still in the ground, so that is an ideal time to take routine or predictive samples. When diagnosing crop damage, take samples as soon as you see damage and then again around harvest. For questions about sampling for nematodes, contact your local Extension agent, personnel of the Nematode Assay Lab, or the authors of this paper.

Foliar Symptoms

While diagnosis by a professional is generally needed to confirm the cause of crop damage, there are a number of symptoms that can alert growers to nematode problems. Foliar symptoms of root-knot nematode infection are often similar to those caused by nutrient deficiency or diseases and include stunted, yellowed plants (Figure 6). These symptoms often occur in oval or irregular patches in the field corresponding to areas of greater plant-parasitic nematode densities. The size of the areas damaged will generally increase in size and severity over time and will often correspond to uneven environmental conditions, such as soil type. In severe cases, plants may have necrotic tissue (brown, dying leaves) or entire plants may die in patches of the field (Figure 7). Plants infected with root-knot nematodes may also wilt more than healthy plants during hot, dry conditions—particularly late in the season (Figure 8). This symptom is most noticeable during the heat of the day, and plants recover later in the day as the air temperature cools. Sting nematode infection can cause severe stunting and chlorosis (Figure 9), leading to reduced plant stands (Figure 10). These are symptoms that tend to appear early in the crop season. Lesion nematode typically causes little to no foliar symptoms, but under severe infestation, patchy chlorosis and stunting may occur.

 

Figure 6. A commercial peanut field in early August with patchy chlorosis (yellowing) due to heavy root-knot nematode infestation.
Figure 6.  A commercial peanut field in early August with patchy chlorosis (yellowing) due to heavy root-knot nematode infestation.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 7. Patches of stunted, dying, and yellowing (chlorotic) peanut plants due to nematode damage.
Figure 7.  Patches of stunted, dying, and yellowing (chlorotic) peanut plants due to nematode damage.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 8. Commercial field with dead peanut plants and general wilting due to severe root-knot nematode infestation in non-irrigated field under drought stress. Symptoms are more severe in a susceptible cultivar (left) than resistant (right).
Figure 8.  Commercial field with dead peanut plants and general wilting due to severe root-knot nematode infestation in non-irrigated field under drought stress. Symptoms are more severe in a susceptible cultivar (left) than resistant (right).
Credit: Zane Grabau, UF/IFAS

 

 

Figure 9. Peanut affected by sting nematode (right) has severely-stunted roots and shoot as well as chlorotic (yellow) foliage. The healthy plant on the left is from an area of the same field with little to no sting nematode infestation.
Figure 9.  Peanut affected by sting nematode (right) has severely-stunted roots and shoot as well as chlorotic (yellow) foliage. The healthy plant on the left is from an area of the same field with little to no sting nematode infestation.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 10. Stunted, chlorotic (yellow) plants and reduced stand due to plant death caused by sting nematode.
Figure 10.  Stunted, chlorotic (yellow) plants and reduced stand due to plant death caused by sting nematode.
Credit: Zane Grabau, UF/IFAS

 

Below-Ground Signs and Symptoms

Stunted root systems and reduced yield are common, generalized symptoms of plant-parasitic nematode infec­tion. Specific below-ground symptoms vary by nematode. Root-knot nematode infection is characterized by irregular swellings, called galls, on the pods, roots, or pegs (Figures 11, 12, and 13). These galls are caused by an increase in the size and number of cells triggered by root-knot nematode feeding. Galls contain one or more sedentary adult female root-knot nematodes. These nematodes are contained in the roots and are small, about 1 mm in diameter, so it is difficult to view them in the field. However, with some practice, or the aid of a nematologist, it is possible to excise these pearly white females from the roots and see them—a hand lens will make the examination easier. Gall size will vary based on the severity of the infection; galls may coalesce over portions of the pegs, pods, and roots. The amount of galling is dependent on the densities of nematodes and timing of the infection.

 

Figure 11. Root-knot nematode causes irregularly shaped growths (galls) on peanut pods (left) while noninfested pods are free of galls (right).
Figure 11.  Root-knot nematode causes irregularly shaped growths (galls) on peanut pods (left) while noninfested pods are free of galls (right).
Credit: Zane Grabau, UF/IFAS

 

 

Figure 12. Severe galling on peanut peg with one raised gall on peanut pod. Damage from peanut root-knot nematode.
Figure 12.  Severe galling on peanut peg with one raised gall on peanut pod. Damage from peanut root-knot nematode.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 13. A peanut root system with heavy galling (irregular swellings of the root) due to infection by root-knot nematodes.
Figure 13.  A peanut root system with heavy galling (irregular swellings of the root) due to infection by root-knot nematodes.
Credit: Zane Grabau, UF/IFAS

 

Take care to distinguish galls on the root from nitrogen-fixing nodules that cover much of the roots (Figure 14). Nitrogen-fixing nodules are an important part of plant health and are spherical attachments that are easily re­moved from roots. These nodules often have pink interiors when cut in half due to the present of N-fixing bacteria. Galls are irregular swellings of the root itself and cannot be detached without destroying the integrity of the root. Galled roots may show different degrees of root rot because they are favorite sites for secondary infection by plant pathogens. Female root-knot nematodes exude gelatinous egg masses, sac-shaped structures containing hundreds of nematode eggs, either inside the root or on the root surface. These brown egg masses are very small, about 1 mm, which makes them difficult to see, particularly if roots are not washed free of soil debris. Because egg masses are sticky, soil debris clings to the root surfaces (Figure 15).

 

Figure 14. Healthy peanut root (right) compared to a peanut root infected with root-knot nematode. Both roots have spherical nitrogen-fixing nodules attached to the sides of the root. The infected root exhibits galling, irregular swelling of the root itself, as a result of root-knot nematode infection.
Figure 14.  Healthy peanut root (right) compared to a peanut root infected with root-knot nematode. Both roots have spherical nitrogen-fixing nodules attached to the sides of the root. The infected root exhibits galling, irregular swelling of the root itself, as a result of root-knot nematode infection.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 15. Soil clings to the surface of peanut roots infected by root-knot nematode due to the sticky root-knot nematode egg masses produced at the root surface.
Figure 15.  Soil clings to the surface of peanut roots infected by root-knot nematode due to the sticky root-knot nematode egg masses produced at the root surface.
Credit: Zane Grabau, UF/IFAS

 

Lesion nematode damage is most easily visible on pegs and pods where small, irregular shaped, brown lesions occur. Lesion nematodes migrate within the peg and pod tissue in a wandering motion. This motion pattern may leave distinct trails that distinguish nematode lesions from the more oval lesions caused by pod rot organisms (Figure 16). At higher densities, or as the infection progresses, lesions may darken and coalesce, and often there is an increased incidence of root or pod rot. Heavily infected pegs are weakened, often resulting in pods being dislodged during harvest. Sting nematodes can stunt or stop root growth in part or, in extreme cases, all of the root system (Figure 17). Sting nematode often infects the growing point, which prunes lateral roots, and causes necrotic (brown/black) or swollen root tips. As new lateral roots develop close together and are pruned, the root system gets a bearded appearance (Figure 17). Sting nematode infection on pegs and pods is characterized by singular, pin-point-sized brown lesions (Figure 18).

 

Figure 16. Circular, light brown lesions of necrotic tissue on pods from lesion nematode infestation.
Figure 16.  Circular, light brown lesions of necrotic tissue on pods from lesion nematode infestation.
Credit: Danielle Sprague, UF/IFAS

 

 

Figure 17. Pin-prick sized, brown lesions of necrotic tissue caused by sting nematode.
Figure 17.  Pin-prick sized, brown lesions of necrotic tissue caused by sting nematode.
Credit: Zane Grabau, UF/IFAS

 

 

Figure 18. Peanut root system severely affected by sting nematode (right) exhibiting general stunting, necrosis (dark brown decaying regions), and pruning of lateral roots. A more healthy root system is illustrated in the plant on the left.
Figure 18.  Peanut root system severely affected by sting nematode (right) exhibiting general stunting, necrosis (dark brown decaying regions), and pruning of lateral roots. A more healthy root system is illustrated in the plant on the left.
Credit: Zane Grabau, UF/IFAS

 

Management

Once plant-parasitic nematodes infest a field, it is not possible to eradicate them. Rather, the goals are to minimize crop damage and to keep nematode densities low, ideally at a level where no crop loss occurs. The best way to manage a nematode problem is to use a combination of the most effective and economical practices for the given production situation based on nematode infestation levels, other pest and pathogen problems, available equipment, economics, and other considerations.

Exclusion

Exclusion is taking steps to stop or slow the spread of one or more plant-parasitic nematodes from infested to non-infested fields. Nematodes do not actively migrate from field to field; rather, they are transported in infested soil, water, or plants. Wind, rain, and animals move these materials, but they are most readily carried on farming equipment. Besides avoiding intentionally moving soil or plant material, cleaning these materials from field equipment can slow nematode movement. This is particularly important when working both infested and non-infested areas. Nematodes can also be brought in on infected planting material. Nematodes do not infest peanut seed but can be found in soil, roots, or pods if these materials are mixed with peanut seed.

Crop Rotation

Producers can use crop rotation to reduce nematode densities by growing a crop that supports little to no reproduction of the particular nematode (poor or non-host crop). In the absence of a host on which to reproduce, the nematode population decreases as a portion of the nema­todes die through natural processes. As an aid for choosing rotation crops to manage nematodes, the host status to plant-parasitic nematodes of peanut is listed in Table 1 for selected crops. Grasses, such as bahiagrass, millet, and sorghum-sudangrass are effective rotation crops for the pea­nut and Javanese root-knot nematodes. Cotton and peanut are good rotation partners for managing root-knot nematodes because the root-knot nematodes that infect peanut do not infect cotton, whereas the cotton or southern root-knot nematode (Meloidogyne incognita) does not infect peanut. Corn is generally an intermediate option, typically helping manage peanut root-knot nematode (the most common nematode pest of peanut), but potentially increasing problems if the less common Javanese root-knot nematode is present.

Both lesion and sting nematodes have wide host ranges, so it is difficult to find a crop rotation that helps manage these nematodes based on current knowledge. Watermelon may be an effective rotation crop for managing sting nematode, but may not be a practical fit for all agronomic crop producers. Grasses are especially good hosts for sting and lesion nematodes and should be avoided where these nematodes are a concern. Weed management is an impor­tant supplement to crop rotation because plant-parasitic nematode population densities can be maintained or increased on weedy hosts, including volunteer peanut, nutsedge, morning glory, Alyce clover, and citron, all of which are commonly found in peanut fields in Florida.

Fallow and Cover Cropping

Offseason periods when a cash crop is not grown should also be considered as part of a crop rotation strategy. These periods are opportunities to reduce or exacerbate nematode problems. Fallowing fields in the offseason can help reduce nematode densities, but only if weedy nematode hosts, including volunteer peanut, are controlled. However, erosion can be a major problem when fallowing fields, particularly on sandy soils.

If you grow a cover crop, choose a non-host for the nematodes present in your field. Table 1 includes a summary of the host status of selected cover crops for root-knot and sting nematodes. Most common winter grain cover crops are poor hosts of root-knot nematodes, although this varies by cultivar and nematode species, and some are good hosts of sting nematode. Additionally, some cover crops, such as Brassicas (radish, mustards, etc.), may have nematicidal properties, directly reducing densities of nematodes, although not typically to the same degree as chemical products.

Even cover crops with nematicidal properties are hosts of certain nematodes, such as most Brassicas for root-knot nematodes. Nematode reproduction on a good host will generally counteract any nematicidal effects, so host status should be considered for these cover crops as well. For further information on cover cropping for nematode management, see these UF/IFAS publications on cover crops for root-knot nematodes (https://edis.ifas.ufl.edu/in892), sunn hemp (https://edis.ifas.ufl.edu/ng043), cowpea (https://edis.ifas.ufl.edu/in516), and marigolds (https://edis.ifas.ufl.edu/ng045).

Resistant Cultivars

Some peanut cultivars with a high level of resistance to root-knot nematodes are available. These resistant cultivars prevent or reduce reproduction by root-knot nematodes but are not known to reduce reproduction by lesion, sting, or ring nematodes. Three runner-type peanut cultivars, Tifguard, 'Tifguard,' 'TifNV High O/L,' and 'Georgia 14N,', are highly resistant to root-knot nematodes (Figure 19). These cultivars are also resistant to Tomato spotted wilt virus (TSWV). 'TifNAV' and 'Georgia 14N' are high-oleic varieties. All three cultivars are reported to share two RKN resistance genes, which results in a highly effective source of resistance. However, growing them repeatedly in a monoculture is not advisable because this practice may result in the selection of resistance-breaking within the root-knot nematode populations. There is no information currently available on how long it would take resistance-breaking populations to build up, but including non-hosts of the peanut and Javanese root-knot nematodes and RKN-susceptible peanut cultivars in a crop rotation system may slow their development.

When employing resistant cultivars for nematode management, it is important to obtain seed from a reliable source that ensures a high level of quality control, such as a certified seed source. For resistance to be maintained, the seed source must ensure a high level of purity.

 

Figure 19. This on-farm trial illustrates that resistant cultivars greatly reduce damage from root-knot nematodes. Strips of a susceptible cultivar ('Georgia 06G') exhibit chlorosis (yellowing), necrosis (brown, dying tissue), and poor canopy closure. Strips of a resistant cultivar ('TifNV-High O/L') are greener and more vigorous.
Figure 19.  This on-farm trial illustrates that resistant cultivars greatly reduce damage from root-knot nematodes. Strips of a susceptible cultivar ('Georgia 06G') exhibit chlorosis (yellowing), necrosis (brown, dying tissue), and poor canopy closure. Strips of a resistant cultivar ('TifNV-High O/L') are greener and more vigorous.
Credit: Zane Grabau, UF/IFAS.

 

Nematicides and Other Commercial Products

Nematicides are chemical products intended to reduce nematode densities. To protect workers, consumers, and the environment, nematicides must be used as specified on the label and only on those crops listed on the label. Nematicides labeled for peanut production include fumigants—broad-spectrum pesticides that move through soil as a gas—or nonfumigants—liquid or granular products with a narrow spectrum of activity. Ideally, nematicides improve the chances for a successful crop by reducing crop damage from nematodes. Before applying nematicides, growers should consider whether application is likely to provide an economic return at the given infestation level. If a previous crop of peanut was severely damaged, that is a strong indication that a soil fumigant may need to be applied if peanut is to be grown again in the damaged field.

The fumigant 1,3-dichloropropene (Telone II) is available for use on peanut by a certified applicator and can be effective for managing nematode problems. This product is applied as a liquid that volatilizes once in soil, moving through the soil profile. 1,3-D is often applied in the row at less than the full label rate to reduce input costs and provide an economic return. To ensure maximum efficacy, it is important to apply 1,3-D in a manner that maximizes fumigant movement through the soil profile and thus improves chances for contact with nematodes. This means injecting the fumigant to at least a 10- to 12-inch depth using a shank or other equipment, then sealing and com­pacting the soil. Information on application methods and nematicides labeled for peanut is provided in Table 2.

Metam sodium and metam potassium are broad-spectrum products that are also labeled for nematode management in peanut. They are most commonly used at reduced label rates to aid with suppression of soilborne fungal diseases of peanut. At low rates, they are not very effective for nematode management. They are formulated and applied as liquids, but they do not readily volatilize once in soil, therefore they depend on water to transport them through the upper soil. They must be sprayed over the soil surface and incorporated with a tillage instrument or injected with closely spaced chisels (e.g., 5 to 7 inches apart).

Three chemical nonfumigant nematicides, fluopyram, aldicarb, and oxamyl are currently registered and labeled for Florida peanut production. Oxamyl (Vydate C-LV and Return XL) is liquid spray that can be applied in soil at planting and as a foliar spray after peanut emergence. Fluopyram is a relatively new active ingredient in Velum. For nematode control in peanut production, fluopyram would be applied as an in-furrow spray. Aldicarb is the active ingredient in AgLogic, a granular nematicide/ insecticide that can be applied in-furrow at planting and side-dressed just before pegging. Aldicarb may be familiar to growers as the active ingredient in Temik, a discontinued pesticide.

Non-fumigant nematicides are often less consistently effective than fumigants (Table 3), but also less costly to apply. Non-fumigant nematicides work by coming into contact with nematodes in the soil, or, if the product has systemic activity, by being taken up by the plant. Therefore, the ability of a product to dissolve and move in water (solubility) and the length of time it takes for the compound to break (persistence) greatly influence the efficacy of non-fumigants. Mobile non-fumigants (AgLogic and Vydate C-LV) are likely to come in contact with nematodes in the soil more quickly than poorly mobile non-fumigants, but also risk washout with excess rainfall. A highly persistent nematicide (Velum) will stay in the soil longer, increasing exposure to nematodes. Human toxicity of these products, and thus required handler precautions, also vary by nematicide. Finally, proper application is important and specified on the latest nematicide label instructions. In general, non-fumigants are most effective when they are uniformly applied to moist soil and targeted toward the future rooting zone of the plant, where they will contact nematodes or be absorbed by the plant.

A commercial product (Melocon WG) that contains live spores of the fungus Purpureocillium lilacinum (formerly named Paecilomyces lilacinus) is also labeled for nematodes on peanut, although previous testing suggests it is not as effective as chemical nematicides. The product can be used in organic production and should be applied around planting and again before pegging (Table 2). Melocon WG is formulated as a solid and must be stored in a cool location (70°F or less), not mixed with or exposed to other chemicals, and applied with at least 20 gallons of water per acre because the product contains live organisms.

Other Practices

Practices that promote plant health may help plants better tolerate nematode infection even if they do not reduce nematode populations. This includes practices such as maintaining soil fertility and tilth, providing adequate water, and managing insects and plant pathogens. Good knowledge of environmental and biological properties of your soil can also be a tool in nematode management. As mentioned above, soil type and texture influence where nematode damage is likely to occur.

Some soils keep plant-parasitic nematode densities low despite a susceptible crop. This suppression often develops gradually over a period of time. Practical and tested methods for developing suppressive soils have not been established, but natural predators and pests of nematodes are one cause of nematode-suppressive soils. Recognizing suppressive soils by monitoring nematode densities and cropping history can help cut costs by eliminating unnecessary management practices.

Selected References

Branch, W. D., and T. B. Brenneman. 2015. "Registration of 'Georgia-14N' peanut." Journal of Plant Registrations 9:159–161. https://doi.org/10.3198/jpr2014.11.0082crc

Burris, E., D. Burns, K. S. McCarter, C. Overstreet, M. Wolcott, and E. Clawson. 2010. "Evaluation of the effects of Telone II (fumigation) on nitrogen management and yield in Louisiana Delta cotton." Precision Agriculture 11:239–257.

Chen, Z., and D. Dickson. 1998. "Review of Pasteuria penetrans: Biology, ecology, and biological control poten­tial." Journal of Nematology 30:313–340.

Grabau, Z.J., M.D. Mauldin, A. Habteweld, and E.T. Carter. 2020. "Nematicide efficacy at managing Meloidogyne arenaria and non-target effects on free-living nematodes in peanut production." Journal of Nematology. 52:e2020-28. https://doi.org/10.21307/jofnem-2020-028

Hagan, A., H.L. Campbell, K.L. Bowen, and L. Wells. 2020. "Cultivar selection and nematicide impacts peanut root knot, other diseases, and yield, 2019." Plant Disease Management Reports 14:CF154.

Johnson, A. W., C. C. Dowler, and Z. A. Handoo. 2000. "Population dynamics of Meloidogyne incognita, M. are­naria, and other nematodes and crop yields in rotations of cotton, peanut, and wheat under minimum tillage." Journal of Nematology 32:52–61.

Kinloch, R., and D. Dickson. 1991. "Comparison of winter and spring soil fumigation with 1,3-D for the management of Meloidogyne arenaria on peanut." Journal of Nematology 23:682-685.

Koenning, S., C. Overstreet, J. Noling, P. Donald, J. Becker, and B. Fortnum. 1999. "Survey of crop losses in response to phytoparasitic nematodes in the United States for 1994." Journal of Nematology 31:587–618.

Kokalis-Burelle, N., D. M. Porter, R. Rodriguez-Kabana, D. H. Smith, and P. Subrahmanyam (eds.) 1997. Compendium of peanut diseases. Second ed. The American Phytopatho­logical Society, Saint Paul, MN.

Kutsuwa, K., D. W. Dickson, J. A. Brito, A. Jeyaprakash and A. Drew. 2015. "Belonolaimus longicaudatus: An emerging pathogen of peanut in Florida." Journal of Nematology 47:87–96.

Moore, S. R., and K. S. Lawrence. 2012. "Rotylenchulus reniformis in cotton: Current methods of management and the future of site-specific management." Nematropica 42:227–236.

Oka, Y. 2010. "Mechanisms of nematode suppression by organic soil amendments—A review." Applied Soil Ecology 44:101–115. https://doi.org/10.1016/j.apsoil.2009.11.003

Thomas, S., J. Schroeder, and L. Murray. 2005. "The role of weeds in nematode management." Weed Science 53:923–928. https://doi.org/10.1614/WS-04-053R.1

Rodriguez-Kabana, R., N. Kokalis-Burelle, D.G. Robertson, C.F. Weaver, and L. Wells. 1995. "Effects of partridge pea peanut rotations on populations of Meloidogyne arenaria, incidence of Sclerotium rolfsii, and yield of peanut." Nematropica 25:27-34.

Wang, K., R. McSorley, R. N. Gallaher, and N. Kokalis- Burelle. 2008. "Cover crops and organic mulches for nematode, weed and plant health management." Nematol­ogy 10:231–242. https://doi.org/10.1163/156854108783476412

Tables

Table 1. 

Host status of selected cash and cover crops for management of specific plant-parasitic nematodes of peanut.1

Crop

Peanut root-knot nematode2

Javanese root-knot nematode

Sting nematode2

Agronomic or forage crops

Bahiagrass

Poor/non-host

Unknown3

Good host

Carinata

Good host

Good host

Unknown

Corn

Poor/non-host

Good host

Good host

Cotton

Poor/non-host

Poor/non-host

Good host

Millet

Varies by cultivar

Varies by cultivar

Good host

Potato

Good host

Varies by cultivar

Good host

Sesame

Varies by cultivar

Good host

Unknown

Sorghum

Poor/non-host

Varies by cultivar

Good host

Soybean

Varies by cultivar4

Varies by cultivar4

Good host

Sugarcane

Unknown

Good host

Good host

Tobacco

Good host

Good host

Poor/non-host

Fruit or vegetable crops

Field pea

Good host

Good host

Good host

Melon (specialty)

Good host4

Good host4

Good host

Snap bean

Good host

Good host

Good host

Tomato

Good host4

Good host

Good host

Watermelon

Good host

Good host

Poor or non-host

Selected cover crops

Sudan grass

Poor/non-host

Poor/non-host

Good host

Winter oats

Poor/non-host

Varies by cultivar

Good host

Winter rye

Varies by cultivar

Varies by cultivar

Good host

Winter wheat

Varies by cultivar

Varies by cultivar

Good host

1 Information is based on observations and literature at the time of publication. Relationships may differ for specific nematode populations and crop cultivars. A good host will increase nematode populations. A poor host will decrease them.

2 Host range of peanut root-knot nematode varies by race or population. There is evidence that physiological or geographic races of sting nematode also exist, but these are not well-established.

3 Bahiagrass is a poor or non-hosts of most root-knot nematode species but has not been tested against the Javanese root-knot nematode

4 This crop is a good host of the specified nematode, but some resistant cultivars or rootstocks are available.

Table 2. 

Nematicides labeled for use in Florida peanut production and labeled rates, timing, and application methods.1

 

Nematicide (active ingredient)

Maximum Rate2

Application Timing

Application Methods

Non-fumigant nematicides

Velum (Fluopyram)

6.5-6.84 oz/acre.

At planting

In-furrow spray.

Propulse (Fluopyram)3

13.6 oz/acre

At pegging

Foliar spray followed by irrigation or rain

Aglogic (aldicarb)

7 lb/acre at planting and 10 lb/acre pre-pegging. See label for additional restrictions.

At planting and (optional) just before pegging.

1. At planting: Apply granules in-furrow and cover with soil. 2. Pre-pegging: side-dress granules in open furrow and immediately cover with soil.

Vydate C-LVor Return XL (Oxamyl)4

136 oz/acre per year total. 34-68 oz/acre at planting. 17 oz/ acre per foliar application. (5 applications/year maximum.)

At planting and 14+ days after peanut emergence.

1. At planting: spray in 7" band behind planter. Apply in-furrow or incorporate by tillage. 2. Broadcast or banded foliar spray in conjunction with a separate pre-plant nematicide. For banded applications, reduce material applied.

MeloCon WG (live bacteria)

6 lb/acre at, just before, or just after planting and 6 lb/ acre before pegging.

Around planting and pre-pegging.

A variety of options. See label. Always apply with a minimum of 20 gallons of water per acre.

Fumigants5

Telone II (1,3-Dichloropropene)4

12 gal/acre. (3-7 gal/acre typical) Rates may be concentrated in the row.

7+ days pre-plant5.

Soil fumigation. Consult label for instructions on fumigant application requirements.

Vapam HL (Metam sodium)4

75 gal/acre. Consult label for in-row rates.

14+ days pre-plant5.

Soil fumigation. Consult label for instructions on fumigant application requirements.

Kpam HL (Metam potassium)4

60 gal/acre. Consult label for in-row rates.

14+ days pre-plant5.

Soil fumigation. Consult label for instructions on fumigant application requirements.

1 Provided as guidelines only and information is subject to changing product registration and labelling. Always read and follow label instructions. The mention of a product or trade name does not imply endorsement to the exclusion of other products.

2 Do not exceed greatest listed label rate. Growers can apply products at less than the labeled rate, but the product may not be as effective. Rates are for total field area, which includes treated and untreated areas for banded applications.

3 Propulse also includes the fungicide prothiocanzole.

4 Multiple products may be available for each of the active ingredients: 1,3-Dichloropropene, oxamyl, metam sodium, and metam potassium. Consult label for application instructions for these products.

5 Fumigants are toxic to plants, so fumigant residues must dissipate before planting. The amount of time needed for residues to dissipate will vary based on soil type and environmental conditions.

Table 3. 

Characteristics of nematicides in Florida peanut.

Active Ingredient

Trade Name(s)

Handler Toxicity Category1

Re-entry interval2

Soil Movement (Water Solubility)

Persistence in Soil (Half-Life)

Systemic in Plant?

Relative efficacy against nematodes3

Live Paecilomyces fungi

MeloCon WG

Caution

4 hours

N/A

N/A

No

Poor to Fair

Fluopyram

Velum or Propulse

Caution

12 hours

Low

(10 ppm)

Long

(162–746 days)

Yes, limited movement

Poor to Good

Aldicarb

AgLogic 15GG

Danger

48 hours

High

(6,000 ppm)

Short

(15 days)

Yes

Fair to Good

Oxamyl

Vydate C-LV/Return XL

Danger

48 hours

High (280,000 ppm)

Medium

(1-4 weeks)

Yes

Poor to Good

1,3-Dichloropropene

Telone II (and others)

Danger

5 days

High, fumigant

Short

(2 to 14 days)

No

Fair to Excellent

Metam Sodium

Vapam HL

(and others)

Danger

5 days4

High (722,000 ppm)

Short

(12 hours to 7 days)

No

Poor to Good

Metam Potassium

K-pam HL

(and others)

Danger

5 days4

High (722,000 ppm)

Short

(12 hours to 7 days)

No

Poor to Good

1 EPA-designated terms on product labels to alert handlers to toxicity hazards. "Danger" is the greatest hazard level, followed by "Warning" and "Caution." Aldicarb, oxamyl, 1,3-Dichloropropene, metam sodium, and metam potassium are restricted use pesticides.

2 Re-entry interval listed is for re-entry without personal protective equipment (PPE). Earlier re-entry may be allowed with proper PPE under certain conditions. See product labels for details.

3 Efficacy scale is none to excellent and is based on common application methods and rates in Florida peanut. Efficacy may vary by situation and should be used as a guide only. Ratings are based on published and unpublished peanut research trials, or other crops if unavailable, in Florida and the surrounding states (Kinloch and Dickson 1991; Rodriguez-Kabana et al. 1995; Grabau et al. 2020; Hagan et al. 2020).

 

 

Publication #ENY069

Release Date:April 12, 2021

Related Experts

Grabau, Zane

Specialist/SSA/RSA

University of Florida

  • Critical Issue: Agricultural and Food Systems

The use of trade names in this publication is solely for the purpose of providing specific information. UF/IFAS does not guarantee or warranty the products named, and references to them in this publication do not signify our approval to the exclusion of other products of suitable composition.

Use pesticides safely. Read and follow directions on the manufacturer's label.

Commercial

About this Publication

This document is ENY069, one of a series of the Entomology and Nematology Department, UF/IFAS Extension. Original publication date February 2018. Revised February 2021. Visit the EDIS website at https://edis.ifas.ufl.edu for the currently supported version of this publication.

About the Authors

Zane J. Grabau, assistant professor; and Donald W. Dickson, professor emeritus, Entomology and Nematology Department; UF/IFAS Extension, Gainesville, FL 32611.

Contacts

  • Zane Grabau