common name: pickleworm
scientific name: Diaphania nitidalis (Stoll) (Insecta: Lepidoptera: Pyralidae)
Distribution - Life Cycle and Description - Host Plants - Damage - Natural Enemies - Management - Selected References
Pickleworm is a tropical insect which routinely survives the winter only in south Florida and
perhaps south Texas. Peña et al. (1987a) documented the overwintering biology in south Florida,
but overwintering has been observed as far north as Sanford, in central Florida, during mild
winters. Pickleworm is highly dispersive, and invades much of the southeast each summer.
North Carolina and South Carolina regularly experience crop damage by pickleworm, but often
this does not occur until August or September. In contrast, northern Florida is flooded with
moths each year in early June as warm, humid tropical summer weather conditions become
firmly established. Although it regularly takes one or two months for the dispersing
pickleworms to move north from Florida to the Carolinas, in some years they reach locations as
far north as Michigan and Connecticut.
The pickleworm can complete its life cycle in about 30 days. Over much of its range, multiple
and overlapping generations may occur. The number of generations was estimated to be four in
Georgia (Dupree et al. 1955) and two or three in North Carolina (Fulton 1947).
Egg: The eggs are minute, measuring only about 0.4 to 0.6 mm in width and 0.8 mm in length.
The shape varies from spherical to flattened. Their color is white initially, but changes to yellow
after about 24 hours. The eggs are distributed in small clusters, usually two to seven per cluster.
They are deposited principally on the buds, flowers, and other actively growing portions of the
plant. Hatching occurs in about four days (Smith 1911). Elsey (1980) estimated egg production
to be 300 to 400 eggs per female.
Larva: There are five instars. Total larval development time averages 14 days. Mean duration
(range) of each instar is about 2.5 (2-3), 2 (1-3), 2 (1-3), 2.5 (2-3), and 5 (4-7) days, respectively.
Head capsule widths for the five instars are about 0.25, 0.42, 0.75, 1.12, and 1.65 mm,
respectively (Smith et al. 1994). Body lengths average 1.6, 2.5, 4.0, 10, and 15 mm during
instars 1 through 5, respectively. Young larvae are nearly white in color with numerous dark
gray or black spots. The dark spots are lost at the molt to the fifth instar. Larval color during the
last instar is somewhat variable, depending largely on the insect's food source. Prior to pupation
larvae tend to turn a dark copper color. When mature, larvae often attain a length of 2.5 cm.
young larva
mature larva
Pupa: Pupation usually occurs in a leaf fold; often dead, dry material is used. There is only
weak evidence of a cocoon, usually just a few strands of silk. The pupa is elongate, measuring
about 13 mm in length and 4 mm in width. It is light brown to dark brown in color, and tapers to
a point at both ends. Pupation usually lasts about eight to nine days.
Adult: Emerging moths fly during much of the evening hours, but most flight occurs three to
five hours after sundown, with peak flight at approximately midnight (Valles et al. 1991). The
female moth produces a pheromone that attracts males, with peak production occurring at five to
seven hours after sunset (Valles et al. 1992). Moths are fairly distinctive in appearance. The
central portion of both the front and hind wings is a semi-transparent yellow color, with an
iridescent purplish reflection. The wings are bordered in dark brown. The wing expanse is about
3 cm. Both sexes often display brushy hairpencils at the tip of the abdomen. Moths are not
found in the field during the daylight hours, and probably disperse to adjacent wooded or weedy
areas during the heat of the day. Moths do not produce eggs until they are several days old.
adult
Pickleworm feeds on both wild and cultivated cucurbit species. Creeping cucumber, Melothria
pendula, is considered to be an important wild host. Wild balsam apple, Mormordica chorantia,
which has also been reported to be a host, is of questionable significance (Elsey et al. 1985).
Summer squash and the winter squash species are good hosts. Pumpkin is of variable quality as
a host, probably because pumpkins have been bred from several Cucurbita species. The
Cucumis species, cucumber, gerkin, and cantaloupe, are attacked but not preferred. Among all
cucurbits, summer squash is most preferred, and most heavily damaged. Cultivars vary widely in
susceptibility to attack, but truly resistant cultivars are unknown (Dilbeck et al. 1974).
Pickleworm may damage summer and winter squash, cucumber, cantaloupe, and pumpkin.
Watermelon is an unusual host. The blossom is a favored feeding site, especially for young
larvae. In plants with large blossoms, such as summer squash, larvae may complete their
development without entering fruit. They may also move from blossom to blossom, feeding and
destroying the plant's capacity to produce fruit. Very often, however, the larva burrows into the
fruit. The larva's entrance is marked by a small hole, through which frass is extruded. The
presence of the insect makes fruit unmarketable, and fungal or bacterial diseases often develop
once entry has occurred. When all blossoms and fruit have been destroyed, larvae will attack the
vines, especially the apical meristem. Cantaloupe is not a preferred host, and larvae often seem
reluctant to burrow into the fruit. Rather, they feed on the surface or "rind", causing scars. Thus, pickleworm is sometimes referred to as "rindworm," though their feeding is not restricted to the surface and they sometimes burrow into the fruit.
damage
damage
frass
Pickleworm has several natural enemies, but none reliably suppress damage. Generalist
predators such as Calosoma spp. and Harpalus (both Coleoptera: Carabidae), the soldier beetle Chauliognathus pennsylvanicus DeGeer (Coleoptera: Cantharidae), and the red imported fire ant Solenopsis invicta Buren (Hymenoptera: Formicidae) have been reported to be important mortality factors. Also, several parasitoids are known, including Apanteles sp., Hypomicrogaster diaphaniae (Muesebeck), Pristomerus spinator (Fabricius) (all Hymenoptera: Braconidae), Casinaria infesta (Cresson), Temelucha sp. (both Ichneumonidae), and undetermined trichogrammatids (Peña et al. 1987b, Capinera 1994). The braconid Cardiochiles diaphaniae Marsh (Hymenoptera: Braconidae) has been imported from Colombia and released into Florida and Puerto Rico in an attempt to obtain higher levels of parasitism (Smith et al. 1994), and apparently has established in the latter location.
Sampling. It is very difficult to scout for this insect and predict its appearance. Moths are not
attracted to light traps, and pheromone traps have had limited success (Elsey et al. 1991, Valles
et al. 1991). Pheromone lures are not currently available commercially. Brewer and Story
(1987) developed sampling plans for pickleworm larvae in squash. They suggested that the most
reliable sampling unit is the large green staminate flower bud. However, the small eggs, night-
flying behavior, and inability to trap the insect reliably lead most growers to depend on
preventative applications of insecticides.
Insecticides. Cucurbit producers in areas where pickleworm damage is likely to occur usually
apply chemical insecticides from the onset of fruiting through harvest. The internal feeding
behavior of larvae, which is so difficult to detect at harvest, causes particular emphasis on
prevention of damage. In areas that are on the fringe of the normal range there are many seasons
when damage will not occur, but producers apply insecticides as a preventative measure because
prediction of occurrence is so difficult.
Pollinators, particularly bees, are very important in cucurbit production, and insecticide
application can interfere with pollination by killing bees. If insecticides are to be applied when
blossoms are present, it is advisable to use insecticides with little residual activity, and to apply
insecticides late in the day, when honeybee activity is minimal.
Insect Management Guide for vegetables
Biological control. The entomopathogenic nematode Steinernema carpocapsae has been shown
to effectively suppress pickleworm injury in squash (Shannag et al. 1994). Nematode survival is
quite good in large-blossomed squash, where the nematodes can kill the young pickleworm
before it burrows into the fruit. This approach is probably ineffective for species with small,
open blossoms such as cucumber, however, because the nematodes die quickly when exposed to
sunlight. Bacillus thuringiensis will kill pickleworm, but is usually not recommended because
the internal feeding behavior puts the feeding larvae beyond the reach of a stomach-active toxin.
Cultural practices. It is possible to cover plants with screen or row covers to prevent moths
from depositing eggs on the foliage (Webb and Linda 1992). However, because the plants must
be pollinated, usually by honey bees, some allowance must be made to leave the plants
uncovered. Given the night-flying behavior of the moths and the daytime activities of
honeybees, this is not a difficult task on a small planting but is prohibitive on large acreage.
Some growers are able to prevent plant injury through careful timing of their cropping cycle. By
planting early, it is often possible to harvest part of the crop before pickleworms appear.
Smith (1911) reported that squash could be used as a trap crop to keep pickleworm from
attacking cantaloupe, a less preferred host. He recommended that destruction of squash
blossoms, or even the entire plant, be done periodically to keep pickleworms from exhausting the
food supply and then moving onto adjacent cantaloupes. In contrast, Dupree et al. (1955)
reported unsatisfactory results with trap cropping.
- Brewer MJ, Story RN. 1987. Larval spatial patterns and sequential sampling plan for
pickleworm, Diaphania nitidalis (Stoll) (Lepidoptera: Pyralidae), on summer squash. Environmental Entomology 16: 539-544.
- Capinera JL. 1994. Pickleworm and melonworm. Pages 140-145 In Rosen D, Bennett FD, Capinera JL (eds.). Pest Management in the Subtropics: Biological Control -- A Florida
Perspective. Intercept, Andover, United Kingdom.
- Capinera JL. 2001. Handbook of Vegetable Pests. Academic Press, San Diego. 729 pp.
- Dilbeck, J.D., J.W. Todd, and T. Canerday. 1974. Pickleworm resistance in Cucurbita.Florida Entomologist. 57: 27-32.
- Dupree M, Bissell TL, Beckham CM. 1955. The pickleworm and its control. Georgia Agricultural Experiment Station Bulletin N.S. 5: 1-34.
- Elsey KD. 1980. Pickleworm: mortality on cucumbers in the field. Environmental Entomology 9: 806-809.
- Elsey KD, Klun JA, Schwarz M. 1991. Forecasting pickleworm (Lepidoptera:
Pyralidae) larval infestations using sex pheromone traps. Journal of Economic Entomology 84: 1837-1841.
- Elsey KD, Peña JE, Waddill VH. 1985. Suitability of potential wild hosts of Diaphania
species in southern Florida. Florida Entomologist.
68: 682-686.
- Kelsheimer EG. 1949. Control of insect pests of cucumber and squash. Florida Agricultural Experiment Station Bulletin 465. 15 pp.
- Peña JE, Waddill VH, Elsey KD. 1987a. Population dynamics of the pickleworm and
the melonworm (Lepidoptera: Pyralidae) in Florida. Environmental Entomology 16: 1057-1061.
- Peña JE, Waddill VH, Elsey KD. 1987b. Survey of native parasites of the pickleworm,
Diaphania nitidalis Stoll, and melonworm, Diaphania hyalinata (L.) (Lepidoptera: Pyralidae), in southern and central Florida. Environmental Entomology 16: 1062-1066.
- Smith HA, Capinera JL, Peña JE, Linbo-Terhaar B. 1994. Parasitism of pickleworm
and melonworm (Lepidoptera: Pyralidae) by Cardiochiles diaphaniae (Hymenoptera:
Braconidae). Environmental Entomology 23: 1283-1293.
- Smith RI. 1910. Insect enemies of cantaloupes, cucumbers and related plants. North Carolina
Agricultural Experiment Station Bulletin 205. 40 pp.
- Smith RI. 1911. Two important cantaloupe pests. North Carolina Agricultural Experiment Station Bulletin 214:101-146.
- Valles SM, Capinera JL, Teal PEA. 1991. Evaluation of pheromone trap design,
height, and efficiency for capture of male Diaphania nitidalis. (Lepidoptera: Pyralidae) in a field
cage. Environmental Entomology 20: 1274-1278.
- Valles SM, Heath RR, Capinera JL. 1992. Production and release of sex pheromone by
Diaphania nitidalis (Lepidoptera: Pyralidae): periodicity, age, and density effects. Annals of the Entomological Society of America 85: 731-735.
- Webb SE, Linda SB. 1992. Evaluation of spunbounded polyethylene row covers as a
method of excluding insects and viruses affecting fall-grown squash in Florida. Journal of Economic Entomology 85: 2344-2352.
- Wilkerson JL, Webb SE, Capinera JL. (2005). Vegetable Pests III: Lepidoptera. UF/IFAS CD-ROM. SW 182.
Author: John L. Capinera, University of Florida
Photographs: John L. Capinera, University of Florida
Project Cordinator: Thomas Fasulo, university of Florida
Publication Number: EENY-164
Publication Date: October 2000. Latest revision: November 2005.
Copyright: 2000-2005 University of Florida
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Department of Entomology and Nematology
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