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Redbay Ambrosia Beetle Xyleborus glabratus Eichhoff (Insecta: Coleoptera: Curculionidae: Scolytinae)1

Rajinder Mann, Jiri Hulcr, Jorge Peña, and Lukasz Stelinski 2

Introduction

Ambrosia beetles are wood-degrading insects that live in nutritional symbiosis with ambrosia fungi. Typically, ambrosia beetles are considered beneficial because they accelerate the decay of dead trees, which is important for nutrient cycling in healthy forests. The redbay ambrosia beetle, Xyleborus glabratus Eichhoff and its fungal symbiont, Raffaelea sp., are new introductions into the southeastern United States. Xyleborus glabratus was first detected in 2002 and is one of the 10 ambrosia beetle species in the US (Haack 2003, 2006). The beetle transmits the causal pathogen of laurel wilt disease among plants in the Laurel family (Lauraceae), which is caused by one of its fungal symbionts, Raffaelea lauricola (Mayfield and Thomas 2006, Fraedrich et al. 2009). The X. glabratus and R. lauricola complex is considered a "very high risk" invasive disease pest complex having potential equal to that of Dutch elm disease or chestnut blight (Global Invasive Species Database 2010). Laurel wilt is a relatively new disease and much is still unknown about how it will impact the flora of North America.

Distribution

Xyleborus glabratus is native to India, Japan, Myanmar, and Taiwan (Rabaglia 2008). In the US, X. glabratus was first detected in a survey trap near Port Wentworth, Georgia, in 2002 (Rabaglia 2008). In Florida, X. glabratus was first detected in 2005 at the Timucuan Ecological and Historic Preserve in northern Duval County (Mayfield and Thomas 2006). Currently, the redbay ambrosia beetle is an economically important pest in Florida, Georgia, and South Carolina. Recently, the beetle was detected in Jackson County, Mississippi (Riggins et al. 2010); Mobile County, Alabama (Alabama forestry commission 2010); and Bladen County, North Carolina (R. Trickel unpublished results). The pest continues to expand rapidly to new areas posing a threat to redbay and avocado trees in the US and in the countries of Central and South America.

Description

Adult

The adult Xleborus glabratus is a small, elongate, cylindrical beetle about 2 mm in length. It is very similar in appearance to other ambrosia beetles (both native and exotic) already found in the U.S. The combination of its blackish coloration, nearly glabrous upper surface, V-shaped and pointed abdominal tip, and abrupt apical declivity distinguishes this species from other ambrosia beetles occurring in Florida (Mayfield and Thomas 2006). However, expert examination by a specialist is needed for positive identification and confirmation. Males are dwarfed, haploid, flightless, and rarely encountered (Rabaglia 2008).

Figure 1. Dorsal view of an adult female redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 1.  Dorsal view of an adult female redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Lyle J. Buss, University of Florida

Figure 2. Lateral view of an adult female redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 2.  Lateral view of an adult female redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Lyle J. Buss, University of Florida

Figure 3. Dorsal view of an adult male redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 3.  Dorsal view of an adult male redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Lyle J. Buss, University of Florida

Figure 4. Lateral view of an adult male redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 4.  Lateral view of an adult male redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Lyle J. Buss, University of Florida

Egg

Figure 5. Eggs of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff, inside gallery that an adult female constructed.
Figure 5.  Eggs of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff, inside gallery that an adult female constructed.
Credit: Photograph by: Lyle J. Buss, University of Florida

Larva

The larva of Xyleborus glabratus is similar to other scolytid beetles. It is a white, c-shaped, legless grub with an amber-colored head capsule (Rabaglia 2008).

Figure 6. Larvae of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff, inside galleries that adult females constructed.
Figure 6.  Larvae of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff, inside galleries that adult females constructed.
Credit: Photograph by: Lyle J. Buss, University of Florida

Pupa

Figure 7. Two newly emerged (exoskeleton still darkening) adult redbay ambrosia beetles, Xyleborus glabratus Eichhoff, near a white pupa (bottom right) from which the adult has not yet emerged.
Figure 7.  Two newly emerged (exoskeleton still darkening) adult redbay ambrosia beetles, Xyleborus glabratus Eichhoff, near a white pupa (bottom right) from which the adult has not yet emerged.
Credit: Photograph by: Lyle J. Buss, University of Florida

Biology

Currently, very little is known about the life cycle and biology of X. glabratus. However, it is presumed that its biology is similar to that of other species in the Xyleborini (Mayfield and Thomas 2006). Adult females bore into the wood just below the bark and construct galleries in the sapwood, inoculating the galleries with a fungus (Rabaglia 2008, Mayfield and Thomas 2006). Most of the life cycle, including mating, egg laying and larval development, is completed within these galleries. The adults and larvae feed on fungi and not on the wood of the damaged host plant (Rabaglia 2008). Adults are active throughout the year with peak activity in early September (Hanula et al. 2008). In Asia, the beetle has been reported to survive in temperatures ranging from -26°C to 15°C. The flight activity is greatest late afternoon or early evening and the beetles usually fly at or below 15 ft (G. Brar unpublished results).

Figure 8. Life cycle of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff. Top row, left to right: egg; 1st, 2nd and 3rd instar larvae, pupa. Bottom row, left to right: the first three adults are females with progressively darkening exoskeltons, the final adult is a male.
Figure 8.  Life cycle of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff. Top row, left to right: egg; 1st, 2nd and 3rd instar larvae, pupa. Bottom row, left to right: the first three adults are females with progressively darkening exoskeltons, the final adult is a male.
Credit: Photograph by: Lyle J. Buss, University of Florida

Most native ambrosia beetles attack only dead and dying trees. However, X. glabratus initiates attacks on healthy redbay trees. The beetles drill through the bark and inoculate tree xylem with their symbiotic fungi, R. lauricola. The beetle carries the fungus in mandibular mycangia (specialized sacs above mandibles adapted for fungus transport). After becoming infected, redbays wilt within weeks to a few months. The dying tree is also colonized by numerous other ambrosia beetle species, including X. affinis, X. ferrugineus, Xyleborinus saxeseni, and Xylosandrus crassiusculus, which further inoculate the tree with their associated fungi (J. Foltz unpublished results). Beetles reproduce within their galleries and newly emerging females fly in search of new hosts. In the southeast, there could be multiple overlapping generations per year (Global Invasive Species Database 2010). The brood development occurs within 50–60 days (Hanula et al. 2008, G. Brar unpublished results).

Both haplo-diploidy and inbreeding are common in ambrosia beetles including X. glabratus. Females lay both diploid and haploid eggs. The more prevalent diploid eggs develop into females, whereas males hatch from unfertilized haploids eggs. Therefore, males are haploid and flightless clones of their mothers with 50% of her genetic material. The males spend most of their lives inside the natal gallery fertilizing their own sisters. Such sons allow single females to establish successful populations in non-native locations (Kirkendall 1983).

Hosts

The host range of X. glabratus includes plants in the Dipterocarpaceae, Fagaceae, Fabaceae, and Lauraceae families in Southeast Asia (Rabaglia et al. 2006).

The complete host range of X. glabraus in the US is unknown. However, all investigated American members of the Lauraceae family have been found susceptible to the disease (Ploetz and Peña 2007). The hosts of X. glabartus and laurel wilt in the US include:

  • avocado, Persea americana

  • California bay laurel, Umbellularia californica

  • northern spicebush, Lindera benzoin

  • redbay, Persea borbonia

  • sassafras, Sassafras albidum

  • swampbay, Persea palustris

(Rabaglia et al. 2006; Smith et al. 2009).

The laurel wilt fungus has also been found on two critically endangered shrubs in Florida:

  • pondberry, Lindera melissifolia

  • pondspice, Litsea aestivalis

(Fraedrich et al. 2007).

The beetle also feeds on camphor tree, Cinnamomum camphora, which is listed as a Category I invasive species by the Florida Exotic Pest Plant Council. However, the camphor tree is not on the Federal or State noxious weed list (Florida Exotic Pest Plant Council 2011).

Damage and Sysmptoms

Xyleborus glabratus is the only known vector of R. lauricola (Crane et al. 2008, Fraedrich et al. 2008). Trees attacked by X. glabratus exhibit few external symptoms initially. Small strings of compacted sawdust protrude from the bark at the point of attack; however, these strings disintegrate easily and are not always readily apparent. Removal of bark at the point of attack reveals shot-holes from which a dark stain extends into the surrounding xylem. Initial attacks introduce spores of the fungus into the xylem of the host tree. The fungal infection is visible by stained sapwood upon removal of bark or in cross sections of the stem. The stain is the tree's response to fungal infection that gradually spreads through the outer sapwood.

Figure 9. Small strings of compacted sawdust protruding from the bark at the point of attack are an indication of an infestation by the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 9.  Small strings of compacted sawdust protruding from the bark at the point of attack are an indication of an infestation by the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Michael Flores, University of Florida

Figure 10. Stained sapwood is an indication of an infestation by the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 10.  Stained sapwood is an indication of an infestation by the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Michael Flores, University of Florida

Trees infested with laurel wilt are characterized by a dark discoloration in the outer sapwood. Affected trees exhibit wilted foliage with a reddish or purplish discoloration. Foliar discoloration may occur within a section of the crown or the entire crown. The foliage eventually turns brown and tends to remain on the branches (Fraedrich et al. 2008). In redbay, the fungus moves rapidly through the xylem, plugging the flow of water and causing the trees to die within few weeks or months.

Figure 11. Wilted foliage with a reddish or purplish discoloration caused by an infestation of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Figure 11.  Wilted foliage with a reddish or purplish discoloration caused by an infestation of the redbay ambrosia beetle, Xyleborus glabratus Eichhoff.
Credit: Photograph by: Michael Flores, University of Florida

Spread

Xleborus glabratus is presumed to have been introduced into the U.S. through solid wood packing materials (Fraedrich et al. 2007). The cryptic nature of ambrosia beetles makes them difficult to detect in shipments of trees or wood products (Oliver and Mannion 2001, Rabaglia et al. 2006, Koch and Smith 2008). Local spread of beetles is potentially caused by the transport of fuel wood, tree trimmings, and other infested wood products (Rabaglia 2008). Barbecue smoke-wood may also serve as a potential vehicle for moving the beetle and the fungus into new areas. The natural rate of movement of the X. glabratus-laurel wilt complex within forests is estimated up to 34 miles per year (Koch and Smith, 2008). The actual spread could be even faster, especially when aided by human transport. The beetle is attracted to volatiles naturally emitted by living trees, severed limbs, tree stumps, and pruned trees of avocado, Persea americana, and redbay, Persea borbonia (Hanula et al. 2008). Female beetles are believed to be capable of flying 2–3 km in search of a host (Rabaglia 2008).

Management

Currently, there are no methods for preventing further infestation of susceptible trees where redbay ambrosia beetle is established. In Florida trees with signs of rapid wilting, dieback, and insect boring in redbay and other host trees should be reported to the Florida Department of Agriculture and Consumer Services Division of Plant Industry or Division of Forestry.

To avoid spreading the beetle and pathogen to new areas, redbay and other hosts of redbay ambrosia beetle should not be moved or sold as firewood, tree trimmings, or barbecue smoke-wood. Wood from infested trees should not be transported out of the local area where the infested trees are detected. Dead redbay or other Lauraceous tree species cut in residential areas should be chipped and left onsite as mulch, or disposed of as locally as possible. The pathogen does not survive in the mulched wood chips (Spence et al. 2013).

Manuka oil, the essential oil extracted from Leptosperum scoparium and Phoebe oil, an extract of Brazilian walnut (Phoebe porosa) are potent attractants of X. glabratus. Both oils are effective baits for monitoring X. glabratus populations (Hanula and Sullivan 2008).

Chemical control of X. glabratus through aerial sprays is complicated and impractical because adult beetles must be in the immediate area that is treated. Once adult beetles bore into trees, contact insecticides are ineffective. For management of the vector and pathogen in avocado groves, growers should maintain tree health by preventing plant stress caused by abiotic and biotic factors. Ambrosia beetles are known to attack trees suffering from some type of environmental or cultural stress (drought, flooding, freezing, nutrient deficiencies, etc.). Avocado trees with confirmed disease symptoms should be removed to prevent spread of the vector and pathogen (Cameron et al. 2008, Hanula et al. 2008). The infested wood should be burnt within the infested grove without transportation (Crane 2009). Avocado trees not showing symptoms but present adjacent to trees with confirmed symptoms of disease may be treated with contact insecticides to kill flying beetles (Crane et al. 2011). Damaged or pruned avocado wood is more attractive to X. glabratus than non-damaged wood for up to three weeks. Therefore, groves should be pruned during the late fall or winter when X. glabratus activity is low. Groves should be pruned early in the morning and the cut surfaces should be treated with contact insecticides with residual activity (Crane et al. 2011).

Selected References

Alabama Forestry Commission. (November 2010). Redbay ambrosia beetle. http://www.forestry.state.al.us/RedbayAmbrosiaBeetle.aspx (18 April 2011).

Cameron, RS, Bates C, Johnson J. (September 2008). Distribution and spread of laurel wilt disease in Georgia: 2006–08 survey and field observations. Georgia Forestry Commission. U.S. Forest Service. http://fhm.fs.fed.us/em/funded/09/so-em-08-02-report.pdf (18 April 2011).

Crane JH. (March 2009). Issues concerning the control of the redbay ambrosia beetle (Xyleborus glabratus) and spread of the laurel wilt pathogen (Raffaelea lauricola). Avocadosource.com. http://www.avocadosource.com/papers/Research_Articles/CraneJonathan2009.pdf (18 April 2011).

Crane JH, Peña JE, Osborne JL. (December 2008). Redbay ambrosia beetle-laurel wilt pathogen: a potential major problem for the Florida avocado industry. Gainesville: University of Florida Institute of Food and Agricultural Sciences. HS1136. https://edis.ifas.ufl.edu/hs379 (18 April 2011).

Crane JH, Peña JE, Ploetz RC, Palmateer AJ. (2011). Proposed grove strategies. FDACS-Division of Plant Industry. http://www.freshfromflorida.com/content/download/23816/485810/proposed-grove-strategies.pdf (August 2015).

Florida Exotic Pest Plant Council. (February 2011). Florida EPPC's 2009 Invasive Plant Species List. http://www.fleppc.org/list/2009/index.htm (August 2015).

Fraedrich SW, Harrington TC, Rabaglia RJ. (2007). Laurel wilt: a new and devastating disease of redbay caused by a fungal symbiont of the exotic redbay ambrosia beetle. Newsletter of the Michigan Entomological Society 52: 15-16.

Fraedrich SW, Harrington TC, Rabaglia RJ, Mayfield AE, Hanula JL, Eickwort JM, Miller DR. 2008. A fungal symbiont of the redbay ambrosia beetle causes a lethal wilt in redbay and other Lauraceae in the Southeastern United States. Plant Disease 92: 215-224.

Global Invasive Species Database. (May 2010). Xyleborus glabratus (insect). http://www.issg.org/database/species/ecology.asp?si=1536&fr=1&sts=&lang=EN (18 April 2011).

Haack RA. 2003. Intercepted Scolytidae (Coleoptera) at U.S. ports of entry: 1985-2000. Integrated Pest Management Reviews 6: 253-282.

Haack RA. 2006. Exotic bark- and wood-boring Coleoptera in the United States: recent establishments and interceptions. Canadian Journal of Forest Research 36: 269-288.

Hanula JL, Mayfield AE, Fraedrich SW, Rabaglia RJ. 2008. Biology and host associations of redbay ambrosia beetle (Coleoptera: Curculionidae: Scolytinae), exotic vector of laurel wilt killing redbay trees in the southeastern United States. Journal of Economic Entomology 101: 1276-1286.

Hanula JL, Sullivan B. 2008. Manuka oil and phoebe oil are attractive baits for Xyleborus glabratus (Coleoptera: Scolytinae), the vector of laurel wilt. Environmental Entomology 37: 1403-1409.

Kirkendall LR. 1983. The evolution of mating systems in bark and ambrosia beetles (Coleoptera: Scolytidae and Platypodidae). Zoological Journal of the Linnean Society 77: 293-352.

Koch FH, Smith WD. 2008. Spatio-temporal analysis of Xyleborus glabratus (Coleoptera: Circulionidae: Scolytinae) invasion in eastern US forests. Environmental Entomology 37: 442-452.

Mayfield AE, Thomas MC. (July 2009). The redbay ambrosia beetle, Xyleborus glabratus Eichhoff (Scolytinae: Curculionidae). FDACS-Division of Plant Industry. http://www.freshfromflorida.com/pi/enpp/ento/x.glabratus.html (18 April 2011).

Oliver JB, Mannion CM. 2001. Ambrosia beetle (Coleoptera: Scolytidae) species attacking chestnut and captured in ethanol-baited traps in middle Tennessee. Environmental Entomology 30: 909-918.

Ploetz RC, Peña JE. (2007). Laurel wilt: a lethal disease on avocado and other Lauraceous hosts. Caribbeanseeds.com. http://www.caribbeanseeds.com/Laurel-wilt-overview.pdf (18 April 2011).

Rabaglia RJ, Dole SA, Cognat AI. 2006. Review of American Xyleborina (Coleoptera : Curculionidae : Scolytinae) occurring North of Mexico, with an illustrated key. Annals of the Entomological Society of America 99: 1034-1056.

Rabaglia R. (June 2008). Xyleborus glabratus. Exotic Forest Pest Information System for North America. http://spfnic.fs.fed.us/exfor/data/pestreports.cfm?pestidval=148&langdisplay=english (18 April 2011).

Riggins JJ, Smith JA, Mayfield AE, Layton B, Balbalian C, Campbell R. 2010. First occurrence of laurel wilt disease on redbay trees in Mississippi Plant Disease 94: 634.

Smith JA, Mount L, Mayfield AE, Bates CA, Lamborn WA, Fraedrich SW. 2009. First report of laurel wilt disease caused by Raffaelea lauricola on camphor in Florida and Georgia. Plant Disease 93:198.

Spence D J, Smith JA, Ploetz R, Hulcr J, Stelinski LL. 2013. Effect of chipping on emergence of the redbay ambrosia beetle (Coleoptera: Curculionidae: Scolytinae) and recovery of the laurel wilt pathogen from infested wood chips. Journal of Economic Entomology 106(5): 2093-2100.

Footnotes

1. This document is EENY491, one of a series of the Entomology and Nematology Department, UF/IFAS Extension. Original publication date April 2011. Revised August 2015. Reviewed April 2019. 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://entomology.ifas.ufl.edu/creatures.
2. Rajinder S. Mann, postdoctoral research associate, Entomology and Nematology Department, UF/IFAS Citrus Research and Education Center; Jiri Hulcr, postdoctoral research associate, Biology Department, North Carolina State University; Jorge Peña, professor, Entomology and Nematology Department, and tropical fruit entomologist, Tropical REC; and Lukasz Stelinski, assistant professor, Entomology and Nematology Department, CREC; UF/IFAS Extension, Gainesville, FL 32611.

Publication #EENY491

Release Date:April 29, 2019

Related Experts

Pena, Jorge E

Specialist/SSA/RSA

University of Florida

Hulcr, Jiri

Specialist/SSA/RSA

University of Florida

Stelinski, Lukasz L.

Specialist/SSA/RSA

University of Florida

Related Units

  • Critical Issue: Agricultural and Food Systems
Organism ID

Contacts

  • Jiri Hulcr
  • Lukasz Stelinski