Worldwide tests of generic attractants, a promising tool for early detection of non-native cerambycid species
Creators
- Roques, Alain1
- Ren, Lili2
- Rassati, Davide3
- Shi, Juan2
- Akulov, Evgueni4
- Audsley, Neil5
- Auger-Rozenberg, Marie-Anne6
- Avtzis, Dimitrios7
- Battisti, Andrea3
- Bellanger, Richard8
- Bernard, Alexis9
- Bernadinelli, Iris10
- Branco, Manuela11
- Cavaletto, Giacomo3
- Cocquempot, Christian12
- Contarini, Mario13
- Courtial, Béatrice9
- Courtin, Claudine9
- Denux, Olivier9
- Dvořák, Miloň14
- Fan, Jian-ting15
- Feddern, Nina16
- Francese, Joseph17
- Franzen, Emily K. L.18
- Garcia, André11
- Georgiev, Georgi19
- Georgieva, Margarita19
- Giarruzzo, Federica13
- Gossner, Martin16
- Gross, Louis9
- Guarneri, Daniele20
- Hoch, Gernot21
- Hölling, Doris16
- Jonsell, Mats22
- Kirichenko, Natalia23
- Loomans, Antoon24
- Luo, You-qing25
- McCullough, Deborah26
- Maddox, Craig27
- Magnoux, Emmanuelle9
- Marchioro, Matteo3
- Martinek, Petr14
- Mas, Hugo28
- Mériguet, Bruno29
- Pan, Yong-zhi30
- Phélut, Régis9
- Pineau, Patrick9
- Ray, Ann M.31
- Roques, Olivier9
- Ruiz, Marie-Cécile32
- Sarto i Monteys, Victor33
- Speranza, Stefano13
- Sun, Jiang-hua34
- Sweeney, Jon D.35
- Touroult, Julien36
- Valladares, Lionel37
- Veillat, Loïs9
- Yuan, Yuan2
- Zalucki, Myron P.38
- Zou, Yunfan39
- Žunič-Kosi, Alenka40
- Hanks, Lawrence M.41
- Millar, Jocelyn G.39
- 1. INRAE URZF and Beijing Forestry University, Orléans, France|INRAE URZF, Orléans, France
- 2. INRAE URZF and Beijing Forestry University, Orléans, France|Beijing Forestry University, Beijing, China
- 3. University of Padua, Padova, Italy
- 4. Russian Plant Quarantine Center, Krasnoyarsk Branch, Krasnoyarsk, Russia
- 5. Fera Science Ltd., York, United Kingdom
- 6. INRAE URZF, Orléans, France|INRAE URZF and Beijing Forestry University, Orléans, France
- 7. Forest Research Institute, Hellenic Agricultural Organization Demeter, Thessaloniki, Greece
- 8. INRAE UEVT, Antibes, France
- 9. INRAE URZF, Orléans, France
- 10. Plant Health and Research service – ERSA, Pozzuolo Del Friuli, Italy
- 11. University of Lisbon, Lisboa, Portugal
- 12. Unaffiliated, Plougonven, France
- 13. University of Tuscia, Viterbo, Italy
- 14. Mendel University in Brno, Brno, Czech Republic
- 15. Zhejiang Agriculture and Forestry University, Lin'an, China
- 16. Forest Health and Biotic Interactions, Swiss Federal Research Institute WSL, Birmensdorf, Switzerland
- 17. USDA APHIS PPQ S&T, Forest Pest Methods Laboratory, Buzzards Bay, United States of America
- 18. Xavier University, Cincinnati, United States of America|USDA APHIS PPQ S&T, Bethel, United States of America
- 19. Forest Research Institute, Bulgarian Academy of Sciences, Sofia, Bulgaria
- 20. Ente Parco Nazionale del Circeo, Sabaudia, Italy
- 21. BFW – Austrian Research Centre for Forests, Vienna, Austria
- 22. Swedish University of Agricultural Sciences, Uppsala, Sweden
- 23. Siberian Federal University, Krasnoyarsk, Russia|Sukachev Institute of Forest, Siberian Branch of Russian Academy of Sciences, Federal Research Center «Krasnoyarsk Science Center SB RAS», Krasnoyarsk, Russia
- 24. Netherlands Food and Consumer Product Safety Authority, Division Agriculture and Nature (NPPO) National Reference Centre, Wageningen, Netherlands
- 25. Beijing Forestry University, Beijing, China|INRAE URZF and Beijing Forestry University, Orléans, France
- 26. Michigan State University, East Lansing, United States of America
- 27. NSW Department of Primary Industries, Wollongbar & Centre for Tropical Horticulture, Alstonville, Australia
- 28. Laboratori de Sanitat Forestal – CIEF VAERSA- Generalitat Valenciana, Quart de Poblet, Spain
- 29. Office pour les Insectes et leur Environnement (OPIE), Guyancourt, France
- 30. Southwest Forestry College, Kunming, China
- 31. Xavier University, Cincinnati, United States of America
- 32. Office pour l'Environnement de la Corse (OEC), Corte, France
- 33. Universitat Autònoma de Barcelona, Bellaterra, Spain
- 34. Hebei University, Baoding, China|INRAE URZF and Beijing Forestry University, Orléans, France
- 35. Natural Resources Canada, Canadian Forest Service, Atlantic Forestry Center, Fredericton, Canada
- 36. PatriNat (OFB, CNRS, MNHN), Paris, France
- 37. Toulouse University, Toulouse, France
- 38. The University of Queensland, Brisbane, Australia
- 39. University of California, Riverside, United States of America
- 40. Department of Organisms and Ecosystems Research, National Institute of Biology, Ljubljana, Slovenia
- 41. University of Illinois at Urbana-Champaign, Urbana, United States of America
Description
A large proportion of the insects which have invaded new regions and countries are emerging species, being found for the first time outside their native range. Being able to detect such species upon arrival at ports of entry before they establish in non-native countries is an urgent challenge. The deployment of traps baited with broad-spectrum semiochemical lures at ports-of-entry and other high-risk sites could be one such early detection tool. Rapid progress in the identification of semiochemicals for cerambycid beetles during the last 15 years has revealed that aggregation-sex pheromones and sex pheromones are often conserved at global levels for genera, tribes or subfamilies of the Cerambycidae. This possibly allows the development of generic attractants which attract multiple species simultaneously, especially when such pheromones are combined into blends. Here, we present the results of a worldwide field trial programme conducted during 2018–2021, using traps baited with a standardised 8-pheromone blend, usually complemented with plant volatiles. A total of 1308 traps were deployed at 302 sites covering simultaneously or sequentially 13 European countries, 10 Chinese provinces and some regions of the USA, Canada, Australia, Russia (Siberia) and the Caribbean (Martinique). We intended to test the following hypotheses: 1) if a species is regularly trapped in significant numbers by the blend on a continent, it increases the probability that it can be detected when it arrives in other countries/continents and 2) if the blend exerts an effective, generic attraction to multiple species, it is likely that previously unknown and unexpected species can be captured due to the high degree of conservation of pheromone structures within related taxa. A total of 78,321 longhorned beetles were trapped, representing 376 species from eight subfamilies, with 84 species captured in numbers greater than 50 individuals. Captures comprised 60 tribes, with 10 tribes including more than nine species trapped on different continents. Some invasive species were captured in both the native and invaded continents. This demonstrates the potential of multipheromone lures as effective tools for the detection of 'unexpected' cerambycid invaders, accidentally translocated outside their native ranges. Adding new pheromones with analogous well-conserved motifs is discussed, as well as the limitations of using such blends, especially for some cerambycid taxa which may be more attracted by the trap colour or other characteristics rather than to the chemical blend.
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- Figure: 10.3897/neobiota.84.91096.figure1 (DOI)
- Figure: 10.3897/neobiota.84.91096.figure4 (DOI)
- Figure: 10.3897/neobiota.84.91096.figure3 (DOI)
- Figure: 10.3897/neobiota.84.91096.figure2 (DOI)
- Other: 10.3897/neobiota.84.91096.suppl1 (DOI)