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Extension Entomology

Garden Fleahopper

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Article author: Tyler Mays
Most recently reviewed by: Blayne Reed & Ballinger (Vacant) (2021)

Common Name(s): Fleahopper, Garden fleahopper

Description

The garden fleahopper is a small insect roughly 1/16 of an inch in size and is black with yellow spots. The females have two forms: a long wing and a short wing. Males and long-winged females resemble tiny, tarnished plant bugs, and the wings have membranous tips that extend past the end of the abdomen. The forewings of short-winged female lack the membranous portion and resemble the forewings of beetles. Garden fleahoppers can be confused with flea beetles because of their size and jumping habits when disturbed; and aphids because of their small size, but aphids do not hop when disturbed.

Garden fleahoppers are commonly found on the underside of leaves or plant terminals and tend to hop, jump, or fly when disturbed. This insect feeds on the plant’s leaf tissue and young fruiting sites and will give the leaf chlorotic spots due to cells dying, resembling the damage caused by spider mites and can cause malformation or fruit shed of flowing fruit.

Origin and Distribution

The garden fleahopper is a native insect and is widely distributed in the eastern United State of America and Canada. It is also distributed as far west as the Rocky Mountains and southward into the Caribbean as well as Central and South America.

Habitat & Hosts

The garden fleahopper has a wide host range and can be found infesting field crops, ornamentals, and vegetable crops. Commonly infested field crops include alfalfa, clover, sweet clover, and has been observed infesting cotton on the Texas High Plains recently. Ornamental plants infested include chrysanthemum, daisy, marigold, and salvia. Several vegetable plants can be infested including bean, cabbage, cowpea, cucumber, eggplant, lettuce, pea, pepper, potato, squash, sweet potato, and tomato. Garden fleahoppers can also be found feeding on several weedy plants including bindweed, pigweed, mallow, ragweed, and many others.

Life Cycle

The garden fleahopper has an incomplete life cycle (hemimetabolous) and passes through an egg and 5 nymphal instars before becoming an adult. Their life cycle can be completed in roughly 30 days depending on environmental temperatures. Under cold temperatures this insect overwinters (diapause) in the egg stage, and in warmer climates it overwinters as the adult stage.

Eggs are inserted into the leaves and stems of plants at puncture wounds and dead plants are white to yellow in color. Once nymphs hatch from the egg, they are a pale green and become darker shades of green with each instar. The nymph passes through a total of five instars before becoming adults in 11 to 41 days based on the temperature.

Nymphs and adults feed on both leaf and stem tissue by piercing cells and feed on the cell’s contents. This feeding damage causes the cells to die and gives the leaves a stippling appearance with chlorotic spots, similar to the damage caused by spider mites and can cause early fruit shed in squaring cotton or malformation of the flower. Leaves heavily damaged by the garden fleahopper will die prematurely. This damage can also hinder the sale of plants grown for fresh leaves like lettuce and herbs, or the reduce ornamental sales because they are no longer aesthetically pleasing to the customer.

Management

If you live in the State of Texas, contact your local county agent or entomologist for management information. If you live outside of Texas, contact your local extension for management options.

The garden fleahopper can be suppressed easily with labeled insecticides, and therefore tend to be a pest of gardens rather than commercial production sites, but economic populations in both do occur. In gardens these fleahoppers can be managed with home/garden insecticides labeled for aphid management. The eggs are protected from insecticide application because they are inside the plant tissue, and a second insecticide application may be needed once the eggs hatch to reduce damage. Physically removing weedy hosts close to and within or nearby to production sites and gardens can keep garden fleahopper numbers from reaching damaging levels. Natural enemies of the garden fleahopper do exist and can be used to manage their population. These natural enemies include parasitic wasps and a predatory mite among other predacious insects and spiders mobile enough to catch the fleahopper. For management recommendation please contact your local County Extension Office.

Related Publications

Managing Cotton Insects in Texas. https://extensionentomology.tamu.edu/files/2018/03/ENTO075.pdf

Citations

Capinera, John L. 2020. Featured Creatures: Garden Fleahopper. University of Florida Publication: EENY-78. entnemdept.ufl.edu/creatures/veg/leaf/fleahopper.htm. Accessed Nov. 30, 2020

Bessin, Ric. 2019. Garden Fleahopper. University of Kentucky Cooperative Extension Publication:Entfact-307. entomology.ca.uky.du/ef307. Accessed Nov. 30, 2020

Vyavhare, Suhas S., Kerns, David, Allen, Charles, Bowling, Robert, Brewer, M., and Parajulee, M. 2019. Managing Cotton Insects in Texas. Texas A&M AgriLife Publication: ENTO-075. https://extensionentomology.tamu.edu/files/2018/03/ENTO075.pdf. Accessed Nov. 30, 2020

 

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Burrowing Bug

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Article author: Tyler Mays
Most recently reviewed by: Kerry Siders & Ballinger (Vacant) (2020)

Common Name(s): Burrower Bug, Burrowing Bug, Peanut Burrower Bug

Description

The burrower bug is a soil dwelling insect only leaving the soil to migrate to new locations within a field or a nearby field. Their presence and damage is favored by hot and dry weather conditions. Feeding damage by this insect can reduce the quality of peanuts, and in other crops rarely cause economic damage.

Adult burrower bugs are small, roughly ¼” in size and resemble a small stink bug. Adults are black with the tips of the forewings being clear and membranous. Legs of adults are covered in spines.

Immature insects can range in color depending on the exact species of the insect. The immature peanut burrower bug has a grey-tan abdomen with three black spots on the back that are oval in shape.

Habitat & Hosts

Burrower bugs are known to feed on a variety of plants including peanut, soybean, cotton, conr, peppers, strawberry, spinach, oak trees, peach, pear, and more. Burrower bugs occur in high numbers around lights at night during periods in the fall. They can be a pest of crop production and found throughout Texas. This insect is medically harmless.

 

Life Cycle

The burrower bugs belongs to the order Hemiptera, and has an incomplete life cycle (hemimetabolous). The adult female lays its eggs at or just below the soil line and once hatched the nymph resembles the adult without wings. As the insect develops through five instars in the nymph stage, its wings will slowly form. In Texas there appears to be two peaks in the population with the first occurring in mid May to June and the second occurring in late July to August.

Management

If you live in the State of Texas, contact your local county agent or entomologist for management information. If you live outside of Texas, contact your local extension for management options.

The soil dwelling habitat of this insect makes management options complicated. Avoiding dry soil conditions through irrigation will minimize the presence and severity of damage caused by this insect. In row crops chlorpyrifos can be applied, but this insecticide is currently under EPA review and may not be available in the near future. Other insecticides options include bifenthrin, imidacloprid, and/or lambda-cyhalothrin; however, little data has been conducted on the efficacy of these insecticides against the burrower bug. Additionally, the entomopathogenic nematode Heterohabdities bacteriophora has been identified as a potential biological control agent.

Burrower bug damage to peanut kernals. Photo by Steve L. Brown, University of Georgia, Bugwood.org.

Burrower bug damage to peanut kernals. Photo by Steve L. Brown, University of Georgia, Bugwood.org.

Citations

Martini, Xavier and David Wright. 2017. The Peanut Burrower Bug-an Emerging Pest In Peanuts. Feb. 17, 2017. Field Crops, Insects, Peanut, Pest Management. nwdistrict.ifas.ufl.edu/phag/2017/01/17/the-peanut-burrower-bug-an-emerging-pest-in-peanuts

Baughman, Todd, Peter Dotray, James Grichar, Mark Black, Jason Woodward, Calvin Trostle, Scott Russell, Clyde Crumley, Pat Porter, Leon New, Paul Baumann, Mark McFarland. Texas Peanut Production Guide. texaspeanutboard.com/wp-content/uploads/peanutproductionguide.pdf

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Chilli Thrips

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Article author: Extension Entomologist at Weslaco (Vacant)
Most recently reviewed by: Pat Porter & Extension Entomologist at Overton (2020)

Common Name(s): Chilli Thrips, Strawberry Thrips, Yellow Tea Thrips

Description

Chilli thrips, Scirtothrips dorsalis, are tiny (> 2mm long), cigar-shaped insects.  The adults are pale in color with black, feathery wings and dark spots forming incomplete stripes on the top of the abdomen.  Immatures, called larvae, look similar to adults but are even smaller and lack wings. Distinguishing chilli thrips from other thrips species is difficult, requires magnification, and some knowledge of insect taxonomy.  Chilli thrips are most often recognized based on their behavior and the type of damage they cause.

Origin and Distribution

Chilli thrips are thought to originally come from Southeast Asia although they are now widely distributed through most of the world including India, Japan, most of Africa, much of the Caribbean and South America, and are quickly becoming established in the United States.  They were first detected in Florida in 1991 and in Southeast Texas in 2005.  They have been intercepted at various ports-of-entry many times on a wide range of host plants and are likely established in many landscapes from Florida to Texas.  This insect has the potential to become a wide-spread pest throughout the Southern and Pacific U.S.

Habitat & Hosts

Chilli thrips are known to infest an impressively wide range of host plants, more than 225 species from at least 40 different plant families, and the list will likely continue to grow as they expand their range.  Their main wild, or native, host plants are in the bean family, Fabaceae.  Among other known plant hosts are numerous important crops and ornamental plants such as citrus, corn, cotton, eggplant, melon, peanut, pepper, rose, strawberry, tobacco, and tomato.

Unlike similar looking species such as the Western flower thrips, which are often found in flowers feeding on pollen, chilli thrips feed on foliage and are typically found on the undersides of leaves near the mid-vein or borders of leaves. However, when population densities are high, some individuals may be found feeding on the upper surface of leaves.

 

These insects have piercing and sucking mouthparts they use to extract material from individual epidermal plant cells.  Cell death leads to a silvering or bronzing of leaves and may cause them to curl, distort and/or turn brittle and drop from the plant.  Infested plants can become stunted or dwarfed. Chilli thrips tend to favor tender plant tissue, flower buds, and young fruits and vegetables although all above ground parts of plants may be attacked.  Feeding on fruits leads to scarring and, in severe infestations, corky tissues.  Aesthetic damage to ornamental plants can lead to extensive losses in the nursery/horticultural industry.

In addition, chilli thrips are known to vector at least seven viruses to various plants including chilli leaf curl virus, peanut necrosis virus, tobacco streak virus, melon yellow spot virus, watermelon silver mottle virus, and capsicum chlorosis virus, although there are no reports at this time that they have been vectors of any of these viruses in Texas.

Life Cycle

Female thrips insert anywhere from 60 – 200 microscopic, kidney-shaped eggs into plant tissue on or near leaf veins, terminal plant parts and floral structures where they cannot be detected by the naked eye.  Eggs will hatch in 2-7 days.  There are two larval stages that look similar to the adult but are smaller and lack wings.  Larvae feed for 8-10 days before entering a non-feeding pupal stage that lasts 2-3 days.  The length of time it takes to complete their life cycle varies depending on temperature and host plant but ranges from 14 – 20 days.  Their large reproductive capacity and quick generation time means that chilli thrips populations can increase very quickly.

Management

If you live in the State of Texas, contact your local county agent or entomologist for management information. If you live outside of Texas, contact your local extension for management options.

Early detection of chilli thrips is important.  Monitor for leaf silvering, bronzing or distortion, which can be mistaken for herbicide damage.  To sample for thrips, tap the terminal portion of plants over a white piece of paper and examine with a hand lens or magnifying glass.  In nurseries or greenhouses, yellow or blue sticky traps can be used to monitor for thrips.

Chilli thrips do have some natural enemies including minute pirate bugs (Orius sp.), lacewings, and predatory mites.  While these predators may not always be able to provide adequate control of chilli thrips, it is important to preserve them by avoiding broad-spectrum insecticides such as pyrethroids and organophosphates, both of which also have a limited ability to manage chilli thrips .  Biorational insecticides including horticultural oils, spinosad, and insecticidal soaps will kill larvae and adult thrips but have no residual activity so frequent application will be needed to control larvae as they emerge from eggs and/or new thrips migrate in.  Products containing the conventional insecticide imidacloprid can be used as a soil drench or foliar spray and will provide control for a longer period of time with minimal impact on natural enemies. No matter what product you choose, it is important to rotate between different insecticide modes of action to reduce the risk of developing insecticide resistance.

Contributors: Scott Ludwig and Carlos Bogran

Related Publications

Chilli Thrips Control, Identification, and Management. 2016. Yan Chen, Steven Arthurs and Dennis Ring. LSUAg. Available here

Featured Creatures. Chilli Thrips. UF IFAS University of Florida. Available here

Pest Thrips of the United States: Field Identification Guide. Available here

Citations

Ananthakrishnan T. N. 1993. Bionomics of thrips. Annual Review of Entomology 38: 71-92

Chiemsombat, P., O. Gajanandana, N. Warin, R. Hongprayoon, A. Bhunchoth, P. Pongsapich. 2008. Biological and molecular characterization of tospoviruses in Thailand. Archives of Virology 153: 571-577.

Kumar, V., D. R. Seal, G. Kakkar, C. L. McKenzie, and L. S. Osborne. 2012. New tropical fruit hosts of Scirtothrips dorsalis (Thysanoptera: Thripidae) and its relative abundance on them in south Florida. Fla. Entomol. 95: 205 – 207.

Kumar, V., G. Kakkar, D. R. Seal, C. L.  McKenzie, J. Colee, and L. S. Osborne. 2014. Temporal and spatial distribution of an invasive thrips species Scirtothrips dorsalis (Thysanoptera: Thripidae). Crop Protection 55: 80 – 90.

Mound, L. A., and J. M. Palmer. 1981. Identification, distribution and host plants of the pest species of Scirtothrips. (Thysanoptera: Thripidae). Bulletin of Entomological Research 71: 467-479.

Rao, R. D., V. J. Prasada, A. S. Reddy, S. V. Reddy, K. Thirumala-Devi, S. Chander Rao, V.Manoj Kumar, K. Subramaniam, T. Yellamanda Reddy, S. N. Nigam, D. V. R. Reddy. 2003. The host range of tobacco streak virus in India and transmission by thrips. Annals of Applied Biology 142: 365-368.

Reddy, D. N. R., and Puttswamy. 1983. Pest infesting chilli (Capsicum annuum L.) in the nursery. Mysore J. Agric Sci 17: 246 – 251.

Sanap, M. M., R. N. Nawale, 1987. Chemical control of chilli thrips, Scirtothrips dorsalis. Vegetable Science 14: 195 – 199.

Seal, D. R., M. Ciomperlik, M. L. Richards, W. Klassen. 2006. Distribution of the chilli thrips, Scirtothrips dorsalis Hood (Thysanoptera: Thripidae), within pepper plants and within pepper fields on St. Vincent. Florida Entomologist 89: 311-320.

Seal, D. R., W. Klassen, and V. Kumar. 2010. Biological parameters of Scirtothrips dorsalis (Thysanoptera: Thripidae) on selected hosts. Environ. Entomol. 39: 1389 – 1398.

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Soybean Podworm

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Article author: David Kerns, Pat Porter
Most recently reviewed by: (1970)

Common Name(s): Corn earworm, Cotton Bollworm, Sorghum headworm, Soybean Podworm, Tomato Fruitworm

Description

The soybean podworm is also known as the corn earworm, cotton bollworm, sorghum headworm and tomato fruitworm and can be found on many garden and farm crops and non-crop vegetation. In most soybean production, soybean podworm is referred to as corn earworm. Adults have buff-colored wings and rather stout bodies. The wingspan is approximately 1½ inches. They are good fliers and can easily move from field to field and often arrive in large numbers on storm fronts. The moths only feed on nectar and are not pests.

However, each female can lay 500 or more eggs. The eggs are laid singly and, when new, are pearly white. The color changes to a yellow/dull white tint over time before hatching. Small caterpillars look much like the small caterpillars of other species, and it is difficult to identify them without a microscope. Soybean podworm caterpillars have many microspines on the back and sides of the body, and these are not found on most other common caterpillar pests. Larvae have a tan head and alternating dark and light stripes running lengthwise down the body, and they have numerous tubercles (dark spots) with long spines. Other pest species have stripes as well, but they do not have the abundance of microspines and tubercles, and a 10x hand lens will allow differentiation. There is no “typical” larval color, and it is common to find larvae that are either light green, dark green to grey green, or pink. Full grown larvae are approximately 1.5 inches long.

A very similar pest that may be found infesting soybean is the tobacco budworm. Eggs and larvae of soybean podworm and tobacco budworm indistinguishable without fine magnification. Tobacco budworm larvae have a tooth-like projection, called a retinaculum, on the inside surface of the mandibles and fine short hairs on the first, second and eighth abdominal projection (tubercle) which bear a single, prominent spine. If the projection and hairs are absent, this indicates a podworm. Damage and management of these two pests are the same in soybean. Soybean podworm may be distinguished from other soybean infesting caterpillars primarily based on the number of pairs of abdominal prolegs.

 

Origin and Distribution

The soybean podworm is a New World insect (Western Hemisphere) and is present throughout this region. It overwinters only in areas with mild winters, but flies to other areas during the course of the spring, summer and fall.

Habitat & Hosts

Soybean podworm has a very wide host range, and in Texas is usually the caterpillar found in ears of corn. Other cultivated hosts include tomato, sorghum, cotton, sunflower, squash, watermelon, potato, sweet potato, asparagus, artichoke, cowpea, snap pea, green bean, cabbage, cantaloupe, collard, cucumber eggplant, pepper, watermelon and others. The first generation of soybean podworm primarily develops on wild hosts, principally clovers. The second generation develops primarily on corn. Among soybean podworm hosts, corn is the most suitable of all hosts. The third and fourth generations generally occur in other agronomic host crops such as soybean, cotton, and grain sorghum with the fifth generation occurring primarily on volunteer crop plants after harvest and on other non-crop wild hosts.

Host preference of soybean podworm is positively correlated to plant maturity and it strongly prefers plants in the flowering stage. Thus, egg lay in soybean most often occurs during flowering or the R1-R2 stages. Later infestations may occur but are much less common. High infestations of soybean podworm often follow pyrethroid applications during bloom, due to destruction of natural enemies.

Although a less common pest of soybean in Texas, in other parts of the southern U.S. soybean podworm is often the most economically important insect pest of soybean. Soybean podworm causes damage to soybean through defoliation and from consuming pods. Early instars typically feed on blooms and and leaves. Feeding on blooms is not considered economical and defoliation by podworms alone is usually not severe enough to warrant control. Most damage is associated with 3rd-6th instar larvae which will feed upon leaves, but more importantly soybean pods. One larva can consume 15-20 flat pods or 6-10 older pods.

 

Life Cycle

Adults are quite mobile and can lay eggs on any host that is at a susceptible stage. Eggs are often laid near or on fruiting structures, but they can be laid on leaves and stems as well. Eggs hatch in 3-5 days and there will be five to six larval instars, each separated by a molt to a larger caterpillar. The larval stage lasts from 13 to 31 days depending on temperature. Insects develop faster under higher temperatures. After the last larval stage, the larvae move to the soil and construct a burrow where they will remain while in the pupal stage, which lasts from 10 – 25 days depending on temperature. Adults then emerge and will live for an average of 10 days, some more and some less. Soybean podworm overwinters in south Texas, and often flies north carried on storm fronts. There are several generations per year and the insect can be expected to be present for most of the growing season in the south, but only increases gradually in number in northern parts of the state. However, the growing season starts later in the north, and soybean podworm is usually quite abundant by the time vegetables and other crops reach susceptible stages.

Soybean podworm larvae are cannibalistic but in soybean they are usually not confined to groups in small areas so this behavior is inconsequential.

Management

If you live in the State of Texas, contact your local county agent or entomologist for management information. If you live outside of Texas, contact your local extension for management options.

Most states have well defined action threshold to aid in management decision making. Sampling for soybean podworm usually involves sweep net or drop cloth. In much of the southern U.S., pyrethroid resistance is common in soybean podworm populations so caution should be used if using a pyrethroid for podworm control. Commonly used insecticides for soybean podworm and tobacco budworm include products containing chlorantraniliprole, spinetoram or spinosad. Additionally, the nucleaopolyhedrovirus, i.e. Heligen, has proven to be an effective alternative to chemical insecticides.

Related Publications

Citations

Adams, B.P., D.R. Cook, A.L. Catchot, J. Gore, F. Musser, S.D. Stewart, D. L. Kerns, G. M. Lorenz, J.T. Irby and B. Golden. 2016. Evaluation of corn earworm, Helicoverpa zea, (Lepidoptera: Noctuidae), economic injury levels in Mid-South reporductive stage soybean. J. Econ. Entomol. 109: 1161–1166.

Flanders, K. and R. Smith. 2008. Identifying caterpillars in field, forage, and horticultural crops. Alabama Cooperative Extension, ANR-1121. http://www.aces.edu/pubs/docs/A/ANR-1121/ANR-1121.pdf.

Hartstack, A. W., J. P. Hollingsworth, R. L. Ridgway, and J. R. Coppedge. 1973. A population dynamics study of the bollworm and the tobacco budworm with light traps. Environ. Entomol. 2: 244–252.

Mueller, A. J., and B. W. Engroff. 1980. Effects of infestation levels of Heliothis zea on soybean. J. Econ. Entomol. 73: 271–275.

Smith, R. H., and M. H. Bass. 1972. Soybean response to various levels of podworm damage. J. Econ. Entomol. 65: 193–195.

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Cotton aphid/Melon aphid

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Article author: David Kerns
Most recently reviewed by: Pat Porter (2018)

Common Name(s): Cotton Aphid, Melon Aphid

Pest Location

Row Crop, Vegetable and Fruit

Description

Cotton or melon aphids, Aphis gossypii, are highly variable in size and color, varying from light yellow to dark green or almost black. Although size can vary based on environmental conditions, adult aphids tend to be about 1/16th inch in length, are soft bodied and pear shaped. Aphids have piercing-sucking mouthparts and have two protrusions on their rear tips called cornicles. Aphid adults can be winged (alate) or wingless (apterous). The formation of winged types is usually in response to overcrowding or poor host quality. The immatures or nymphs of the aphid are similar in appearance to the adult but smaller.

Origin and Distribution

Cotton aphid is nearly cosmopolitan, having a world-wide distribution. However, host specificity does vary depending on geographic origin.

Habitat & Hosts

Cotton aphids are extremely polyphagous and can feed on a large range of host plants covering 25 plant families. Among many others, notable hosts include asparagus, beans, begonia, catalpa, citrus, clover, cucurbits, cotton, eggplant, ground ivy, gardenia, hops, hibiscus, hydrangea, okra, peppers, potato, spinach, strawberries, tomatoes and violet. Crops typically most affected by cotton aphids include citrus, cotton and hibiscus.

Cotton aphids will initially be found feeding on the underside of new leaves, the plant terminal and flower buds, but as the population grows will infest the under side of older leaves.

Cotton aphids feed using sucking-piercing mouthparts which they use to pierce leaves and ingest copious amounts of plant sap from the phloem. Feeding robs the plant of energy that would otherwise be utilized for growth or fruit production. Heavy and prolonged infestations can cause leaves to curl downward, older leaves to turn yellow and shed, plant fruit may also shed or suffer reduction in size.

Cotton aphids excrete wastes in the form of a syrup-like substance called honeydew. Honeydew will accumulate on the leaves (and other plant structures) giving them a shiny, sticky appearance. A black sooty mold will often grow on the honeydew covering the leaf which may partially inhibit photosynthesis. More importantly, the honeydew may accumulate on the lint of open cotton bolls rendering the lint undesirable for milling.

Cotton aphid is also an important vectors of over 50 plant viruses including cucumber mosaic virus, watermelon mosaic virus 2, and zucchini yellow mosaic virus. These viruses are non-persistent viruses and may be transmitted from aphid to plant in a little as 15 seconds.

Cotton aphids are often attended by ants, which collect an feed upon their honeydew.

Life Cycle

With exception of northern latitudes, cotton aphids in the United States are all females, reproduce asexually (parthenogenically), giving birth to live young without mating. Aphids have a tremendous reproductive capacity and nymphs are born with developing embryos already present; essentially aphids are born pregnant. One female may produce as many as 80 offspring that mature within 8 to 10 days. Thus, it is possible for cotton aphids to have as many as 50 generations per year. These generations also occur as frequently as every 5 to 7 days under optimum conditions. In northern latitudes cotton aphid is capable of producing sexual forms and laying eggs on catalpa and rose of sharon for overwintering purposes.

Wingless adults overwinter in protected areas on catalpa, hibiscus, and a number of weed hosts. In the greenhouse, they can be active year-round. In spring winged females fly to suitable host plants and can disperse great distances via wind and weather fronts.

Management

If you live in the State of Texas, contact your local county agent or entomologist for management information. If you live outside of Texas, contact your local extension for management options.

Predators such as lady beetles, lacewings and syrphid flies, along with parasitoids and aphid-killing fungi are often the most effective means of managing an cotton aphids. These beneficial organisms can effectively prevent aphids from reaching the damaging levels. Aphid tending ants will often protect aphids from predators. Soil and seed applied insecticides offer protection during early plant growth, but foliarly applied insecticides are often necessary on more mature plants. Standard and organically certified insecticides are available, but cotton aphid is notorious for developing resistance to commonly used insecticides so adequate control is not certain.

Related Publications

Citations

Blackman, R.L. and V. F. Eastop. 2000. Aphids on the worlds crops: an identification and information guide 2nd edition. Chichester, UK: John Wiley & Sons Ltd.

Kerns, D.L., J.A. Yates and B.A Baugh. 2015. Economic threshold for cotton aphid (Hemiptera: Aphididae) on Cotton in the Southwestern United States. J. Econ. Entomol.108: 1795-1803.

Suhas, V., D. Kerns, C. Allen, R. Bowling, M. Brewer and M. Parajulee. 2017. Managing cotton insects in Texas. ENTO-075, 38 pp. http://agrilifelearn.tamu.edu/Managing-Cotton-Insects-in-Texas-p/ento-075.htm.

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