Insect borers are a serious issue in Ranch Colony. Many trees have been lost in our community. It is critical that infected trees be removed as quickly as possible to reduce the chance of other near by trees from being infected. The article below is reprinted from the Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida. We hope you find it useful.
E. A. Buss and J. L. Foltz2
Insect borers can be serious aesthetic, economic, and structural pests of trees and shrubs. Their tunneling damages wood, creates "hazard" trees, and lowers the wood's value for lumber and veneer. Infested nursery stock may have poor form, reduced growth rates, or be impossible to sell.
Borer larvae (immatures) and adults make tunnels in the shoots, branches, trunks, or roots of woody plants of all ages and sizes. Eggs of most borer species are laid on or in the bark, and larvae chew into the plant tissue. Most borers are larvae of beetles or moths, but some are wasps or flies. Most insect borers are considered "secondary pests" because they attack only after a plant has been weakened or killed by another stress. Some, however, are "primary pests" and are able to attack and develop in fairly healthy trees and shrubs. Knowing whether insects are primary or secondary pests is critical to assessing and treating plant problems.
The presence of borers is hard to detect until plants or plant parts become damaged or die. Sawdust-like frass (excrement) may be around an exit hole or in a pile on the ground. Sap may ooze from the wounded site. There may be round, oval, or D-shaped holes randomly located on the plant. Insect exit holes can be distinguished from woodpecker holes by the absence of frass. The chewing of some species may be heard by someone standing near the tree.
The severity of plant damage depends on the number and location of insects in the plant tissue. Phloem feeders destroy tissues that transport food and produce new wood and bark. Feeding by a few individuals may produce necrotic lesions, whereas feeding that encircles the stem may kill a branch or the entire tree. Xylem borers make holes in the sapwood that disrupt the flow of nutrients and water as well as structurally weakening the plant. Twig and shoot borers decrease fruit, nut, and seed production by causing branch dieback. Borers may also feed in the succulent callus tissue around grafts, thus preventing the connection of scion and stock. Dead branches, pitch masses, and wood and bark riddled with holes decrease the aesthetic value of plants.
Beetles in this group tunnel beneath the bark of trees. Adult beetles are small, somewhat cylindrical, and reddish-brown to black (Figure 1). Larvae are cream-colored and legless. Signs of infestation include a red or white powdery dust that collects around the entrance holes and in bark crevices. Sap may flow from entrance holes and form small "pitch masses." Over time, the bark looks like its been riddled with "shot" from the small beetle exit holes.
CREDITS: J. L. Foltz, University of Florida
Southern pine beetle is one of the most serious pests of pines in the United States, but normally is a scavenger of dying pines. It becomes a pest when its populations increase. Dendroctonus beetles are distinguished by round posteriors, in contrast to Ips beetles, the abdomens of which are concave posteriorly and have small spines on the wing covers (Figure 1). Adult beetles, active throughout the year whenever temperatures are above 58°F, disperse widely to infest injured, weakened or stressed trees. When abundant, they can attack and overwhelm healthy trees. The presence of pitch masses on the tree trunk may indicate an attack. Adults tunnel beneath the bark constructing frass-packed egg galleries in patterns resembling the letter "S" (Figure 2). The tunneling quickly destroys the phloem and kills the tree. One to 3 months later, the needles of the dead tree turn reddish-brown. Seven or more generations may occur each year.
CREDITS: J. L. Foltz, University of Florida
Figure 2. Gallery patterns for the five species of bark beetles commonly found in southern pines. A, Dendroctonus frontalis. B, D. terebrans. C, Ips avulsus. D, I. grandicollis. E, I. calligraphus.
Black turpentine beetles attack fresh stumps and the lower trunk of living pines, usually below a height of 10 feet. Adult beetles bore into the cambium and make galleries that extend downward. Galleries in the inner bark may be vertical, D-shaped, or fan-shaped. All pine species native to the southeastern U.S. are known to be hosts. Attacks are identified by white to reddish-brown pitch masses about the size of a half dollar. The adult insect is dark brown to black and 3/8 inch long (Figure 1). The posterior end is rounded. The life cycle takes from 2 1/2 to 4 months, and there are 2-4 generations a year in Florida.
Ips engravers (Figure 1) are normally secondary pests, attacking pines stressed by factors such as lightning strikes, root damage, and drought. Occasionally, however, large populations attack and kill young, healthy pines and the tops of older pines. Signs of infestation also include pitch masses and fading foliage color, similar to that of the southern pine beetle. However, their frass-free egg galleries radiate out from a common entrance hole (Figure 2). Ips beetles also transmit bluestain fungi, which disrupt the water transport system of trees. Egg-to-adult development occurs in as little as 4 weeks, so these beetles may also have 7-10 generations per year in Florida.
Ambrosia beetle females bore into twigs, branches, or trunks of apparently healthy, stressed, or freshly cut host material. Attacks on living plants are often near ground level on saplings or at bark wounds on larger trees. Visible symptoms of an infestation include wilted foliage and strings of boring dust from numerous small holes (Figure 3). Ambrosia beetles feed on ectosymbiotic fungi that they introduce into their tunnels and cultivate. Eggs, larvae, and pupae occur together in the tunnels - there are no individual egg niches, larval tunnels, or pupal chambers. The two most common species in Florida are Xylosandrus crassiusculus and Platypus compositus.
CREDITS: Russ Mizell, University of Florida
Figure 3. Solid frass "straws" produced by ambrosia beetles as they bore into a tree.
Adults of this family are called long-horned beetles because their antennae are usually long (Figure 4). Larvae (round-headed borers) tunnel underneath bark and into the wood (Figure 5). The tunnels are oval to almost round in cross section, conforming to the cylindrical shape of the larvae. Larvae of some species are legless, but most have three pairs of small legs. While tunneling, larvae continually pack their tunnels with frass, which looks like compressed wood fibers, or push frass out of the holes they make. This frass, along with the sap exuded by the plant in response to the damage, is often visible on the outside of infested trunks or branches.
CREDITS: L. J. Buss, University of Florida
Figure 4. Twig girdler adult.
CREDITS: L. J. Buss, University of Florida
Figure 5. Round-headed borer.
Twig girdlers are important long-horned beetles. Their damage occurs primarily from egg laying. The grayish-brown adult females (1 1/16 inch long) are active from September to November (Figure 4). They girdle limbs by chewing a V-shaped groove entirely around twigs, branches or terminals. Eggs are inserted into the bark on the girdled part of the branch away from the tree. Girdled limbs eventually break and fall to the ground. Larvae cannot develop in healthy sapwood. Damage can disfigure a young tree and leads to secondary branching, especially if the terminal is attacked. Oak, persimmon, hickory and pecan are common hosts.
Adult beetles are flattened, hard-bodied and bullet-shaped with short antennae (Figure 6). These beetles often have distinctive metallic colors (green, blue, bronze, copper). Larvae (Figure 7) are cream-colored and legless with widened, flattened body segments just behind the head. Thus, when these larvae tunnel beneath bark or in the sapwood they make oval or flattened tunnels in cross section. Galleries are often winding and packed with frass. These beetles are often associated with stressed or wounded trees.
CREDITS: J. Castner, University of Florida
Figure 6. Metallic wood-boring beetle adult.
CREDITS: James Solomon, USDA Forest Service
Figure 7. Larva of Chrysobothris femorata.
These insects are the immature stages of several kinds of moths.
Carpenterworms are large caterpillars that tunnel through the trunks of many tree species. These larvae develop over 1 or 2 years, initially feeding underneath the bark but later tunneling into the sapwood. Outward signs of attack include large piles of sawdust and frass. In the spring, large adult moths with mottled wings emerge.
These daytime fliers are called clearwing moths, and they look superficially like wasps (Figure 8). Eggs are laid at the margins of insect holes, lawnmower cuts, on galls, and other wounds. Newly hatched larvae bore into the phloem and feed beneath the bark. Signs of infestation include wet spots, ejected frass, and masses of sap around damage sites. Infestations can kill branches or entire trees. There are 41 species in Florida.
CREDITS: J. Castner, University of Florida
Figure 8. Peach tree borer (Synthedon exitiosa).
Keeping plants healthy can minimize damage from secondary pests like insect borers.
Avoid other physical injury or stress to tree trunks or roots (e.g., lawn mowers, weed trimmers, digging building foundations, septic tanks, soil compaction, soil added or removed above the roots, drought, flooding, or lightening). Mulch around the trunk to increase the distance between machinery and the plant.
Because many borers are attracted to recent wounds, avoid pruning during adult activity periods.
Place trees and shrubs in properly prepared areas protected from extreme weather conditions.
Follow recommended irrigation and fertilization guidelines.
After trees and shrubs are infested with borers, non-chemical controls are limited.
Remove and destroy (burn or chip) infested, dying or dead plants or plant parts, including fallen limbs. Severely infested trees ("brood trees") only produce more pests that can attack neighboring trees.
Several natural enemies attack insect borers, including predatory beetles, parasitic wasps or flies, and birds, especially woodpeckers.
Insert a flexible, small gauge wire into borer entry holes to puncture and kill the tunneling insect. Several attempts may be needed to be successful.
Use pheromone traps to monitor adult activity, and disrupt the mating and egg-laying of clearwing borers. These traps often only attract males.
Use ultraviolet blacklight traps to monitor adult beetles, which are drawn to the light and die in the bucket. These traps attract both males and females.
Stressed, unhealthy trees may be repeatedly attacked and need repeated insecticide treatments. This is often expensive and not environmentally friendly. The first priority is to improve overall tree health, and use insecticides as a last resort. In addition, most chemicals can only be obtained and applied by licensed professionals with specialized equipment.
Insecticide products registered for borer control are listed in Table 1. Most of these products are applied as sprays to the trunks and branches, and are contact, residual insecticides (e.g., carbaryl, chlorpyrifos, lindane, permethrin). While these products do not kill larvae that have already penetrated the sapwood or heartwood, they will kill adults and larvae tunneling through the treated bark layer. These products are applied preventively and may be effective for 3 to 10 weeks.
Complete spray coverage of all trunk and branch surfaces is necessary for preventive control of borers. Treating only the base of the tree trunk is enough to protect the tree only from a few insects such as the black turpentine beetle and the peachtree borer. Thorough coverage may be difficult on large trees and may result in drift to non-target areas. To minimize drift, spray only on non-windy days. Read the insecticide lable for the proper protective clothing requirements.
Systemic insecticides are often ineffective for borer control and few are labeled for this purpose. Systemics may be applied as foliar sprays, root drenches, or trunk injections. Trunk injections work by delivering pressurized and concentrated insecticides into the tree (Figure 9). However, these injections are most effective against sap-feeding insects and rarely affect woodborer larvae. The process of injecting the insecticide through a narrow tube and into the drilled hole may result in sap staining, and could allow pathogens an entry point. Translocation of the insecticide is unlikely in partially girdled areas. The use of these products has not been studied in Florida.
CREDITS: E. A. Buss, University of Florida
Figure 9. Mauget injectors are one of several methods for applying systemic insecticides.
Fumigants (e.g., paradichloro-benzene (PDB) moth crystals) can kill caterpillar larvae at the base of trunks if the crystals are inserted into tunnels with external openings, such as for carpenterworms or clearwing borers.
Drooz, A. T. 1985. Insects of eastern forests. Misc. Publ. 1426. Washington, DC: U.S. Department of Agriculture, Forest Service. 608 pp.
Johnson, W. T. and H. H. Lyon. 1991. Insects that feed on trees and shrubs. Comstock Publishing Associates, Ithaca, NY. 560 pp.
Solomon, J. D. 1995. Guide to insect borers of North American broadleaf trees and shrubs. Agric. Handbk. 706. Washington, DC: U.S. Department of Agriculture, Forest Service. 735 pp.
Featured Creatures Website: http://creatures.ifas.ufl.edu/
Southern pine beetle in Florida (EDIS publication): http://edis.ifas.ufl.edu/IG147
WoodyBug Website: http://woodypest.ifas.ufl.edu/
Table 1. Chemical names, trade names, and formulations of insecticides available for professional use on trees and shrubs.
1. This document is ENY-327, one of a series of the Department of Entomology and Nematology, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida. Date first printed: October 1993. Revised: June 2003. Please visit the EDIS Website at: http://edis.ifas.ufl.edu
2. E. A. Buss, assistant professor, and J. L. Foltz, associate professor, Entomology and Nematology Department, Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida, Gainesville, 32611.
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 does not signify our approval to the exclusion of other products of suitable composition. All chemicals should be used in accordance with directions on the manufacturer's label. Use pesticides safely. Read and follow directions on the manufacturer's label.
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