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Southern Lyctus Beetle, Lyctus planicollis LeConte (Insecta: Coleoptera: Bostrichidae: Lyctinae)

Angela S. Brammer

The Featured Creatures collection provides in-depth profiles of insects, nematodes, arachnids, and other organisms relevant to Florida. These profiles are intended for the use of interested laypersons with some knowledge of biology as well as academic audiences.

Introduction

The term "powderpost beetle" is often used to describe two families: Anobiidae (deathwatch beetles) and Bostrichidae (false powderpost beetles). The true powderpost beetles, of the subfamily Lyctinae (formerly family Lyctidae) within the family Bostrichidae, earned their common name from the very fine powdery frass found in their tunnels. Eleven lyctine species are known in the US and Canada.

Florida has three Lyctus species and one species each in the genera Minthea and Trogoxylon (both subfamily Lyctinae). Of the three Lyctus species, one is an introduced seed feeder and another is rarely encountered. Only L. planicollis is common and destructive throughout the South.

Figure 1. The appearance of this Lyctus beetle is typical of true powderpost beetles. Lyctines are very small beetles, ranging from 2 mm to 7.5 mm in length. They are generally brown or reddish-brown, as this one is, although they can sometimes be black. The body is elongated and slightly flattened. The head is prominent and is not covered by the pronotum.
Figure 1.  The appearance of this Lyctus beetle is typical of true powderpost beetles. Lyctines are very small beetles, ranging from 2 mm to 7.5 mm in length. They are generally brown or reddish-brown, as this one is, although they can sometimes be black. The body is elongated and slightly flattened. The head is prominent and is not covered by the pronotum.
Credit: Angela S. Brammer, UF/IFAS

Lyctine beetles, also known as lyctid beetles, are second only to termites in their destruction of structural wood. They are serious pests of hardwoods, mainly ash, hickory, oak, maple and mahogany. Lyctines usually infest dry, seasoned wood that is less than five years old. Hardwood-product manufacturers struggle with lyctine infestations. These businesses are concentrated in the South, where the warm, humid climate is favorable to beetle development. Also, lyctine beetles commonly enter the U.S. from the tropics through Southern ports, ending up in lumberyards where the opportunities for reinfestation are great.

Distribution

Lyctine beetles, are common throughout the US and Canada. Although they also occur in natural conditions, lyctines are closely associated with humans. They travel with people as they move from place to place inside their furniture or other wood products. The beetles can infest wood in one location, be transported with the wood to a new location, and finally emerge thousands of miles away from their origin to reinfest local timber. Lyctines can be found in just about any wood product, including hardwood flooring, hardwood timbers, plywood, crating, furniture, tool handles, ladders, picture frames and baskets, among others. They are also common in lumberyards. The adult beetles may be found throughout the year in buildings but are most commonly found during warmer months due to their increased activity.

Identification

Adults

Lyctus planicollis varies from 4 to 6 mm in length. Lyctines in general are very small beetles, ranging from 2 mm to 7.5 mm in length. They are generally brown or reddish-brown, although they can sometimes be black. The body is elongated and slightly flattened. The head is prominent and is not covered by the pronotum. The antennae have 11 segments, and the last two segments are broadened into a terminal club. The elytra are striated with double rows of small puncture marks between striations. A sparse, short, yellowish pubescence covers the body. Adult lyctine beetles closely resemble flour beetles, but they can be distinguished by the two-segmented club (flour beetles have a three-segmented club). The tibia feature two distinct spurs.

Figure 2. This Lyctus beetle's head is prominent and is not covered by the pronotum, a characteristic of the subfamily Lyctinae (family Bostrichidae). The antennae have 11 segments, and the last two segments are broadened into a terminal club. Adult lyctine beetles closely resemble flour beetles, but they can be distinguished by the two-segmented club (flour beetles have a three-segmented club).
Figure 2.  This Lyctus beetle's head is prominent and is not covered by the pronotum, a characteristic of the subfamily Lyctinae (family Bostrichidae). The antennae have 11 segments, and the last two segments are broadened into a terminal club. Adult lyctine beetles closely resemble flour beetles, but they can be distinguished by the two-segmented club (flour beetles have a three-segmented club).
Credit: Angela S. Brammer, UF/IFAS

 

Figure 3. Adult female southern lyctus beetle, Lyctus planicollis LeConte. Typically, adults are 2 to 7.5 mm long.
Figure 3.  Adult female southern lyctus beetle, Lyctus planicollis LeConte. Typically, adults are 2 to 7.5 mm long.
Credit: USDA Forest Service - Wood Products Insect Lab Archives, USDA Forest Service, www.forestryimages.org

Eggs

The eggs are translucent, about 1 mm long and cylindrical with rounded ends. They usually cannot be seen because the female lays them deep within the pores of the wood.

Figure 4. Southern lyctus beetle, Lyctus planicollis LeConte, eggs. Eggs are usually 1 mm long and translucent or white.
Figure 4.  Southern lyctus beetle, Lyctus planicollis LeConte, eggs. Eggs are usually 1 mm long and translucent or white.
Credit: USDA Forest Service - Wood Products Insect Lab Archives, USDA Forest Service, www.forestryimages.org

Larvae

The larvae are yellowish-white, "C-shaped," and about 7.5 mm long with an enlarged spiracle on the eighth abdominal segment.

Figure 5. Larvae of southern lyctus beetle, Lyctus planicollis LeConte.
Figure 5.  Larvae of southern lyctus beetle, Lyctus planicollis LeConte.
Credit: USDA Forest Service - Wood Products Insect Lab Archives, USDA Forest Service, www.forestryimages.org

Pupae

Figure 6. Pupae of southern lyctus beetle, Lyctus planicollis LeConte.
Figure 6.  Pupae of southern lyctus beetle, Lyctus planicollis LeConte.
Credit: USDA Forest Service - Wood Products Insect Lab Archives, USDA Forest Service, www.forestryimages.org

 

Life Cycle and Biology

Lyctus planicollis, like other lyctine beetles, undergoes complete metamorphosis. It hibernates as a larva, pupates in the spring, and emerges as an adult in the early summer. Typically, the entire life cycle takes about a year, but can be as short as six months or as long as four years depending on environmental conditions. In heated buildings, development can occur more quickly. The larval stage is the one responsible for most of the damage, and the length of this stage accounts for the variability in the length of the life cycle.

Adult lyctines mate soon after emerging from the wood. The female then begins laying eggs in pores on the surface of a piece of wood (either the one she has emerged from or another suitable one). Egg-laying continues for about a week. Powderpost beetles only lay eggs on bare, unfinished wood. They will oviposit in small cracks and crevices in the wood as well as in the pores on the surface.

Depending on temperature, eggs can take one to three weeks to hatch. The young larvae bore deeper into the wood through the bottom of the pore in which they hatched. Larvae tend to feed along the grain of the wood, but in later instars, they will cross the grain. As they feed, they fill the tunnels with the powder like frass that gives them their common name. Just like drywood termites, the larvae may tunnel all the way to the surface of the wood, eating away most of the material there, but they will not break the surface. Because of this behavior, heavily infested wood has a paper-like outer layer that is easily broken. Generally, the larvae confine their feeding to the sapwood. Thanks to indoor heating, they can develop in all seasons, but normally, most activity occurs in the spring and summer. When it is ready to pupate, a larva bores close to the surface and builds a pupal chamber. The pupal stage can last anywhere from 12 days to a month under normal conditions.

The new adult chews its way to the surface and emerges, leaving behind a 0.8 to 1.5 mm circular hole. Emergence occurs most commonly from April to July. Adult lyctines are nocturnal. They hide in cracks and crevices during the day. At night, they will fly to lights. Most adults live one to three months. Recent emergence holes are common sites of oviposition. An average female lays about 15 to 50 eggs during this time.

Lyctines can live in wood with a moisture content of about 6 to 30 percent, but the greatest activity occurs between 10 and 20 percent. Starch content needs to be 3 percent or higher to make an attractive oviposition site for a lyctine beetle. Powderpost beetles feed on the starchy content of the wood; they do not digest cellulose or lignin because they cannot produce cellulases (enzymes that break down cellulose in the gut). Because of this, their activity is restricted to sapwood.

Damage

Lyctines prefer new wood, only rarely infesting wood more than five years old. They also attack bamboo. The most common infestations are found in new homes or newly manufactured wood products. In most cases, the wood was already infested with eggs or larvae at the time of purchase because it was not stored or dried properly.

Most infestations are found in wood paneling, door and window frames, hardwood floors and furniture. Subfloors, joists and rafters often escape infestation because they are usually made of pine or other softwoods. Because of poor storage and drying practices prior to shipment, imported tropical hardwoods are sometimes heavily infested with lyctines.

External signs of damage are often not readily apparent until the adults emerge, leaving holes in the wood. Any slight movement will cause powdery frass to cascade from the emergence holes, collecting below the infested wood in little piles that homeowners sometimes mistake for sawdust. The diameter of the frass piles is proportional to the height of the holes. If an infested piece of wood is cut open, the interior may contain a large amount of loosely packed frass. Occasionally, so much frass can collect that it may burst the papery skin of the wood. When rubbed between the fingers, lyctine frass feels like talc or flour.

Figure 7. The small emergence holes typical of a lyctine beetle infestation can be seen in this pecan limb.
Figure 7.  The small emergence holes typical of a lyctine beetle infestation can be seen in this pecan limb.
Credit: USDA Forest Service - Wood Products Insect Lab Archives, USDA Forest Service, www.forestryimages.org

The presence of emergence holes does not necessarily signify an active infestation. Sometimes an infestation will die out on its own over time. Dealing with lyctine damage can often be confusing and frustrating to property owners who get conflicting reports from different sources about whether the infestation is active or not. Powderpost beetles damage wood relatively slowly. Take the time necessary to weigh all factors involved before deciding on the most appropriate course of action.

Management

Several options exist for handling infestations of L. planicollis and other lyctines. The right choice for a given situation depends on the severity of the infestation, the location of the infestation, the potential for reinfestation, and cost.

Wood varnishes will prevent lyctines from laying their eggs in the pores on the surface of the wood. Beetles found in wood that has been varnished, sealed, painted or waxed were either present in the wood before it was finished or they were able to lay their eggs in the holes left by emerging adult beetles. Sealing any holes in new hardwoods will prevent reinfestation.

Another option is replacing the infested wood. If it can be determined that the infestation is confined to a single piece of wood such as a windowsill, as is often the case, remove the infested piece and replace it with uninfested wood.

Very small articles can be placed in a freezer to kill the adults and larvae. A sustained temperature of 0°F for at least 72 hours is required for this method to be effective. Eggs are very tolerant of cold, and this method may not be entirely effective as a result.

Chemical treatments come in two kinds: surface and fumigation. Fumigation is considered to be the most effective method of lyctine control, but it is also the most costly. If the infestation is widespread, the entire structure may have to be tented and fumigated. Pest control operators can often fumigate furniture or small items such as picture frames or wicker baskets inside a small chamber designed for that purpose. A drawback of fumigation is that it does not provide residual protection of the wood. If a second infestation in a nearby article goes undetected, lyctine beetles can easily reinfest the fumigated item once it is returned to the structure. Surface treatments can be applied to bare, exposed wood by certified pesticide applicators. These insecticides work in two ways. First, they form a toxic barrier on the surface of the wood that kills adults trying to emerge or newly hatched larvae attempting to bore into the wood. Second, in some cases, the insecticide can penetrate the wood deeply enough to kill larvae inside, preventing the appearance of additional emergence holes. Surface treatments generally take a long time, possibly years depending on the life cycle of the species, to be completely effective.

The optimal way to control a structural lyctine beetle infestation would be to prevent the insects from entering the structure in the first place. Although it may not always be possible to detect an early infestation by visual inspection, some infestations will be readily apparent in new wood. Carefully inspect any new hardwood products, including those used in new home construction, before incorporating them into the structure.

For more detailed information, including pesticide labeling, please consult the Insect Management Guide for powderpost beetles.

Selected References

DeAngelis J. (July 1995). Preventing and controlling powderpost beetles in and around the home. Pacific Northwest Extension, Oregon State University, PNW 326. http://owic.oregonstate.edu/sites/default/files/pubs/powderpost_beetles.pdf (October 2023).

Dillon ES, Dillon LS. 1972. A Manual of Common Beetles of Eastern North America, Volume 2. New York: Dover Publications, 894 pp.

Ebeling W. 1975. Urban Entomology. Berkeley: University of California Press, 695 pp.

Hickin NJ. 1972. The Woodworm Problem. London: Hutchinson Benham Ltd., 123 pp.

Ivie MA. 2002. Bostrichidae. In American Beetles; Arnett RH Jr, Thomas MC, Skelley PE, Frank JH (eds.) Boca Raton: CRC Press.

Koehler PG, Oi FM. (January 2003). Powderpost beetles and other wood-infesting insects. ENY-266. Gainesville: University of Florida Institute of Food and Agricultural Sciences. https://edis.ifas.ufl.edu/publication/IG119 (October 2023).

Merchant M. (September 2001). Lyctid powderpost beetles: Suggestions for control. House & Landscape Pest Series, Department of Entomology, Texas A&M University, Ent-1022. http://citybugs.tamu.edu/factsheets/household/termites/ent-2008/ (October 2023).

Papp CS. 1984. Introduction to North American Beetles. Sacramento, Calif.: Entomography Publications, 335 pp.

Rust MK, Paine EO, and Reierson DA. 1997. Evaluation of Freezing to Control Wood-Destroying Insects (Isoptera, Coleoptera). Journal of Economic Entomology 90: 1215–1221.

White RE. 1983. A Field Guide to the Beetles of North America. Boston: Houghton Mifflin. 368 pp.

Williams LH. 1985. Integrated protection against lyctid beetle infestations. U.S. Dept. of Agriculture, Forest Service, Forest Experiment Station. 12 pp.

Wilson SE. 1932. Powderpost beetles. Nature 130: 22–23.

Publication #EENY283

Release Date:October 12, 2023

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About this Publication

This document is EENY283, one of a series of the Entomology and Nematology Department, UF/IFAS Extension. Original publication date March 2003. Revised July 2010, December 2013, and October 2023. Visit the EDIS website at https://edis.ifas.ufl.edu for the currently supported version of this publication. This document is also available on the Featured Creatures website at http://entnemdept.ifas.ufl.edu/creatures/.

About the Authors

Angela S. Brammer, Entomology and Nematology Department; UF/IFAS Extension, Gainesville, FL 32611.

Contacts

  • Elena Rhodes