Skip to main content

MINI REVIEW article

Front. Insect Sci., 12 December 2022
Sec. Invasive Insect Species
This article is part of the Research Topic Focus on Popillia japonica View all 11 articles

A nationwide pest risk analysis in the context of the ongoing Japanese beetle invasion in Continental Europe: The case of metropolitan France

  • 1IGEPP, Institut Agro, Univ Rennes, INRAE, Le Rheu, France
  • 2University of Côte d’Azur, INRAE, CNRS, UMR ISA, Nice, France
  • 3INRAE, University of Bordeaux, UMR Biogeco, Cestas, France
  • 4Expertise and Biological Risks Unit (ERB), Plant Health Laboratory, French Agency for Food, Environmental and Occupational Health and Safety (ANSES), Angers, France
  • 5TERRA, Gembloux Agro-Bio Tech, University of Liege, Gembloux, Belgium

The Japanese beetle, Popillia japonica, is native to Japan and became established in North America in the early twentieth century. The beetle was detected in Europe, first in Italy in 2014 and then in Switzerland in 2017. Metropolitan France is at the forefront of the Japanese beetle threat, due to its geographical proximity to the European populations established in the Piedmont, Lombardy and Ticino regions. An express pest risk analysis for metropolitan France was therefore conducted. The most likely pathways for entry include (i) natural dispersion, (ii) trades of plant products with adherent soil and (iii) hitchhiking behaviour, leading to a high probability of entry. The spread rate of P. japonica was also evaluated as high, resulting from natural spread as well as human activities. Given the absence of significant limiting factors, the potential impacts of P. japonica in France will likely be as important as in its current geographic distribution. Although several sources of uncertainty were highlighted throughout the evaluation, none of them has significant impact on the conclusions of the present express pest risk analysis. Measures to prevent entry, establishment and spread of P. japonica are recommended and include surveillance with pheromone traps and control via integrated pest management strategies. However, most efforts should be concentrated on eradication measures while P. japonica is still in the early stages of invasion.

Introduction

The Japanese beetle, Popillia japonica Newman (Coleoptera, Scarabaeidae), is native to Japan (1). In the early twentieth century, it became established in North America, especially in the USA where it was initially introduced in the states bordering the Atlantic coast. Then, it quickly spread westwards (2) and became one of the worst invasive pests, inflicting severe damage to many cultivated and ornamental plants, trees, fruits, turfs and grasses. Its damage has been estimated to be $460 million per year in the USA (3).

Based on the severity of the economic, social and environmental impacts that P. japonica can cause in the European Union territory (4, 5), the European Commission classified P. japonica as a priority quarantine pest listed in Annex IIB of Regulation 2019/2072, subject to compulsory control and to a national sanitary emergency response plan, in accordance with European Regulation (EU) 2016/2031. Specific requirements are defined for imports of certain plants for planting because of their likelihood of harbouring P. japonica, depending on their origin ((EU) 2021/2285). Despite these efforts, the beetle was detected in Europe, first in Italy in 2014 (6, 7) and then in Switzerland in 2017 (8), two countries where it is now considered established. A few adults were also trapped in south-western Germany in 2021 and 2022 (9, 10), yet these sightings were considered as incursions without establishment.

The challenge for Europe is to counteract this invasion at a very early stage to significantly enhance the chances of successful eradication or containment. Because metropolitan France (i.e. mainland France and Corsica as well as nearby islands in the Atlantic Ocean, the English Channel and the Mediterranean Sea) is at the forefront of the P. japonica threat, the French Agency for Food, Environmental and Occupational Health & Safety (ANSES) was asked to carry out an express pest risk analysis (PRA thereafter; 11), based on the European and Mediterranean Plant Protection Organization (EPPO) express PRA scheme (12), in order to better and quickly prepare the State services for the implementation of measures in the case of a suspected and to implement control measures in the case of a confirmed outbreak. The presumed time horizon of the assessment is five years as suggested by EPPO (13). Following the recommended guidelines for performing an express PRA (12), we aimed at assessing the risks of entry, establishment, and spread of P. japonica in France as well as its potential impacts. Based on the overall risk, recommendations for surveillance and management measures in the event of an outbreak were formulated.

Assessment of the phytosanitary risk

Brief overview of the pest

Popillia japonica is generally a univoltine species (as observed in Japan, Italy and Switzerland) but its development can spread over two years under colder climates (1, 14, 15). The beetle spends most of its life underground in immature forms (eggs, three larval stages and pupae) and a few months above ground as an adult. In Italy, adults are active from June to September with an activity peak in mid-July (16). P. japonica is a dietary generalist: larvae can feed on the rootlets of all host plants while adults preferentially feed on leaves but also on fruits and flowers. The symptoms caused by P. japonica adults are easily observed and consist of skeletonization, adults chewing the leaf tissue between the veins. An updated overview of the host plants of P. japonica (17) emphasises how polyphagous the beetle is (Figure 1): the adults feed on at least 401 host plants belonging to 92 botanical families including fruit trees (e.g. apple, plum), forest species (e.g. maple, poplar), field crops (e.g. corn, soybean) or vegetables (e.g. asparagus, beans), ornamental plants (e.g. roses), herbaceous species (species of the genus Festuca, Lolium and Poa used in lawns and turfs), wild species (e.g. clovers, brambles) and vines. Among this great diversity of host plants, Tayeh et al. (17) identify 131 species as “main” hosts, insofar as they favour the survival and reproduction of P. japonica. We focused on these main hosts in the following pest risk analysis.

FIGURE 1
www.frontiersin.org

Figure 1 Phylogeny of the main and secondary host plants of P. japonica generated by the V.Phylomaker package (18). A total of 131 host plants, belonging to 39 families, are classified as “main” (17). This figure is also available as Supplementary Material to allow for magnification.

Pathways for entry

Entry of a pest is the movement of a pest into an area where it is not yet present, or present but not widely distributed and being officially controlled (19). For each pathway, a sequence of events was evaluated: (1) probability of the pest being associated with the individual pathway at origin, (2) probability of survival during transport or storage, (3) probability of surviving existing pest management procedures, and (4) probability of transfer to a suitable host or habitat. Six pathways were identified to assess the likelihood of entry of P. japonica into France: (1) import of plants for planting (except seeds, bulbs and tubers) with adhering soil, (2) natural spread, (3) hitchhiking behaviour, (4) import of soil (including potting soil and compost), (5) import of cut flowers and foliage, and (6) import of fruits. The in-depth assessment of each of these pathways of entry was based on data available in the scientific literature, the situation in the invaded countries and the flow of goods towards France (see Supplementary Material). We concluded that the likelihood of P. japonica entering metropolitan France is high with low uncertainty. The entry will likely occur through natural spread, since the beetle has high flight ability at the adult stage, or by hitchhiking behaviour, given the recent adult sightings in Basel (Switzerland, in 2021) and Baden-Württemberg (Germany, in 2021 and 2022) close to railway track or freight depot (https://gd.eppo.int/reporting/article-7240), in the Valle d’Aosta region (Italy, in 2021) near a motorway service area, and in Sardinia (Italy, in 2021) near the main airport of the island (20). If no regulations were in place, the likelihood of entry would be increased by imports of plants for planting with adherent soil from infested countries, taking into account the probability that the aerial and subterranean stages are associated at the origin and transported, the diversity and volume of the transported goods (such as roses and fruit tree plants especially from Italy), the abilities of the beetles to survive without food (21, 22) during transport, as well as their capacity of transfer to host plants cultivated in France.

Establishment

Establishment is the perpetuation, for the foreseeable future, of a pest within an area after entry (19). It depends mainly on the presence of host plants and a suitable climate in the PRA area. Four factors that can affect the establishment of P. japonica in a new territory have been identified: (1) mild temperature, (2) sufficient humidity for survival and development, (3) presence of host plants and (4) lack of natural enemies. The likelihood of outdoor establishment is considered high, based on the findings from species distribution models (2326), the high diversity and abundance of host plants in metropolitan France (Figure 2), and the limited impact of natural enemies. The uncertainty is considered low. Indeed, the entire French territory, except mountainous areas, is suitable for the establishment of P. japonica, because summer rainfall is sufficient, temperature is favourable and many host plants are available. In addition, irrigation practices increase the likelihood of establishment in the less rainy areas of the Mediterranean region. In contrast, the likelihood of establishment in protected conditions (e.g. greenhouses) is considered low with a moderate level of uncertainty. This is due to several points: (1) the facilities concerned are generally small and subject to various pest management methods, (2) there have been no recent reports of P. japonica in greenhouses, (3) P. japonica populations seem unlikely to be overlooked during regular inspections by growers in indoor conditions.

FIGURE 2
www.frontiersin.org

Figure 2 Species richness in main host plants of P. japonica in each department (NUTS3 region) of metropolitan France.

Spread

Spread is defined as the expansion of the geographical distribution of a pest within an area (19) and relies on natural spread or human-assisted spread. All previous cases of establishment of P. japonica have been followed by spread activity. Natural spread of P. japonica is mainly achieved by the flight of adults, with both male and female imagoes having functional wings. However, it appears that pioneer individuals are more likely to be females (27). Data on flight capabilities are essentially based on analyses of the speed of the colonisation front by P. japonica, especially in the USA and more recently in Italy. The progression of the invasion front is the result of natural spread, probably coupled with hitchhiking, and suggests spreading capabilities of about 10 km per year in the USA (1, 28, 29). Examining the dynamics of the invasion in Piedmont and Lombardy in Italy (30, 31) provides an equivalent estimate. Human activities, resulting in movements of goods and people, may also favour the long-distance spread of P. japonica. In international trade, larvae may be transported in soil attached to the roots of plants for planting, while adult beetles have been intercepted on agricultural products, on packaging and in ships and aircraft (16). Overall, the spread is expected higher than 10 km per year, which is considered a high magnitude according to the EPPO guidance (32). The uncertainty is low, as no barriers to spread within the metropolitan French territory have been identified.

Impact

Within its current invasion range (data collected from the USA and Italy), the magnitude of impact of P. japonica is considered high, with low uncertainty. This results from: (1) high direct damage in terms of loss of yield (fruit crops) and quality (ornamental crops), (2) high indirect costs related to control (especially chemical and biological), (3) the generalist diet of the insect that can affect many production sectors, with significant damage locally. The potential environmental (e.g. increase in phytosanitary treatments, competition with other species) and social impacts (e.g. human health risks, loss of availability of popular ornamental plants) were also considered. In the USA, efforts to control the larval and adult stages were estimated to be around $460 million in 2015 (3). No extensive damage has been recorded in Europe yet, but recent studies (5, 33) suggest substantial potential damage costs. In particular, Straubinger et al. (33) outlined that major grape and wine producing countries like France and Italy would have a potential economic damage of about €92 million and €68 million per year, respectively.

Within the French area at risk of establishment, the magnitude of impact is also considered high with a low uncertainty. This conclusion is mainly supported by (1) the importance of main host plants in terms of area, yield and export volumes, (2) the absence of currently deployed cultural practices that would significantly reduce the impact of P. japonica and (3) chemical control is mainly based on a single family of products (pyrethroids). The main point of uncertainty concerns the level of susceptibility of French varieties of the main host plants to P. japonica.

Overall, the risk posed by P. japonica for the threatened French metropolitan area is considered high with a low uncertainty. This risk is therefore considered as unacceptable and justifies the recommendation of management measures.

Recommendations for pest risk management

To prevent the entry of P. japonica on the French territory, an efficient surveillance strategy is needed to ensure the early detection and to allow the rapid implementation of eradication measures. Using semiochemical-based traps is recommended along the border with infested countries to detect natural spread, as well as near key entry points and transport networks (e.g. national interest markets, airports, air cargo entry points, railways, ports, road hubs, motorways service areas, and unloading areas) to take the risk of hitchhiking behaviour into account. Pheromone traps should be positioned in preferred habitats such as grasslands, vineyards and fruit crops fields located in the close vicinity of entry points. In addition, visual inspections of the aerial parts of the main host plants of P. japonica are recommended in these areas along the borders with infested countries. Awareness raising of target stakeholders, including for instance nurserymen and garden owners, is also recommended. The use of pheromone-baited traps is the most reliable monitoring method as it is selective and effective. Compared to visual inspection of aerial parts, trapping ensures permanent coverage of the area to be monitored with a higher level of sensitivity.

In case of first capture, we recommend the deployment of a systematic trapping network with one trap every 1 km on a 10 km square, centred on the trap with the first authenticated capture. This 100-km² area would constitute the reinforced surveillance zone within which an infested zone surrounded by a buffer zone would be delimited. We suggest that the delimitation of the infested zone is continuously adapted according to the locations and amount of new captures, following the concept of weighted barycentre (34). The limits of the buffer zone remain to be determined according to new knowledge on the dispersal capacities of the beetle in the colonised area. We currently suggest a 5-km wide buffer based on the dispersal capacity of P. japonica reported in recent studies (35, 36). Since the infested area is a dynamic surface, changing with each discovery of an infestation point, the boundaries of the demarcated area (infested area + buffer zone) would be updated accordingly.

Within the infested area, a combination of measures should be implemented rapidly as part of an eradication strategy: (1) chemical control with the use of authorized active substances against adults and larvae, (2) biological control when available [e.g. entomopathogens such as nematodes (37) or Paenibacillus popilliae (3)], (3) cultural practices involving reduced irrigation during the critical oviposition period (38) and tillage in the fall (39, 40). Importantly, many chemical molecules used in the USA to control P. japonica are banned in the European Union (notably neonicotinoids), restricting the available arsenal essentially to the family of pyrethroids.

The movement of rooted plants, soil and growing media as well as plant wastes originating from the infested area should be prohibited. The same should apply to plants originating from the buffer zone, which should not be moved out. These actions must be carried out within a short period to increase the chances of eradication. Otherwise, the containment strategy is both time consuming and has, in our opinion, little chance of success, since it would at most slow down the spread of P. japonica. Furthermore, the containment strategy involves suppression of P. japonica populations within the infested area by chemical control, biological control and mass trapping, whose effectiveness is reduced in case of heavy infestations.

Discussion and perspectives

Pest risk analyses commissioned at a national level bring out limitations to the precise evaluation of the threat associated with invasive pests and identify opportunities to control their impact. In our study, we addressed specifically the invasive Japanese beetle and its risk to metropolitan France. We assessed the phytosanitary risks in terms of pathways for entry, establishment, spread and economic impacts, and actionable recommendations to mitigate this risk. In this section, we highlight a few points that we believe deserve further attention.

Given the high capacity of P. japonica to hitchhike, it is crucial to identify and quantify the movements of goods and people from infested areas to susceptible regions. Eurostat, the statistical office of the European Union, provides extensive information on flows within well-defined pathways, notably those listed in “pathways for entry”. However, specific custom codes do not allow discriminating goods of particular interest regarding the biology and ecology of P. japonica, making it difficult to capture only relevant information. Furthermore, whether on a national or European scale, if they exist, the accessibility and visibility of data describing the connectivity of means of transport deserve to be improved. Information on freight by road, rail, air, the road traffic during the period of beetle activity, the list of cars and trucks stop locations, unloading areas, etc., would be valuable to better assess the entry routes of the pest.

The biology and ecology of P. japonica have been extensively studied (see for example 1, 4144). However, further knowledge would be useful, such as the attraction radius of pheromone traps for P. japonica. Simple methods exist to estimate this radius (45), useful information to optimise the density of trapping networks. A better understanding of the role of fruit odours on adult feeding attractiveness would also be helpful. Knowing the correlations between the level of susceptibility of host plants and the degree of defoliation should help in assessing the impact on crop yield. It would also be interesting to develop innovative and environmentally sound control strategies that are in line with the European Union commitment to reduce the use of pesticides, such as the use of biological control agents, and the use of attract-and-kill, attract-and-infest, or push-pull strategies.

So far, in continental Europe, P. japonica is still confined to a single and relatively small area of about 14000 square kilometres (20) overlapping northern Italy and southern Switzerland. This early stage of the invasion opens up opportunities for successful control, provided that there is greater harmonisation of the surveillance and control strategy on the European level. For example, the insect is rapidly spreading but information on its presence is not fully centralised, making it difficult to develop and share distribution maps. As pointed out by Thompson et al. (46), surveillance strategy and biosecurity measures should be informed by epidemiological processes rather than limited by administrative boundaries. The interception of an adult Japanese beetle in Basel (in 2021), at the intersection of three countries (France, Germany, Switzerland) illustrates these difficulties. In line with recent publications (4749), we believe that biological invasions could be better regulated by promoting international scientific and technical collaboration to harmonise management practices and regulations.

Author contributions

This review was conducted by the expert working group “Popillia japonica” of the French Agency for Food, Environmental, and Occupational Health and Safety (ANSES). All authors have contributed equally to the risk assessment presented in this document. SP wrote the first draft and all other authors have provided significant inputs into the text. All authors contributed to the article and approved the submitted version.

Acknowledgments

We thank the French Agency for Food, Environmental and Occupational Health and Safety (ANSES) that funded the Pest Risk Analysis conducted by the expert working group “Popillia japonica”.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/finsc.2022.1079756/full#supplementary-material

References

1. Fleming , WE. Biology of the Japanese beetle, technical bulletin. Washington, D.C.: U.S. Department of Agriculture (1972).

Google Scholar

2. USDA. Japanese Beetle distribution in the U.S. APHIS plant protection & quarantine. (2018). Available at: https://www.aphis.usda.gov/plant_health/plant_pest_info/jb/downloads/jb-distribution-map.pdf (Accessed December 1, 2022).

Google Scholar

3. USDA. Managing the Japanese beetle: a homeowner’s handbook. APHIS (2015) 81:25–003.

Google Scholar

4. Baker R, Gilioli G, Behring C, Candiani D, Gogin A, Kaluski T, et al. Report on the methodology applied by EFSA to provide a quantitative assessment of pest-related criteria required to rank candidate priority pests as defined by regulation (EU) 2016/2031. EFSA J. (2019) 17.EFS2. doi: 10.2903/j.efsa.2019.5731

PubMed Abstract | CrossRef Full Text | Google Scholar

5. Sanchez B, Barreiro-Hurle J, Soto Embodas I, Rogriguez-Cerezo E. The impact indicator for priority pests (I2P2): a tool for ranking pests according to regulation (EU) 2016/2031. (EUR 29793 EN). Luxembourg: Publications Office of the European Union (2019).

Google Scholar

6. EPPO RS. EPPO reporting service no. 10. Num. article 2014/179 First report of Popillia japonica in Italy. (2014).

Google Scholar

7. Pavesi M. Popillia japonica specie aliena invasiva segnalata in Lombardia. L’Informatore Agrario (2014) 32:53–5.

Google Scholar

8. EPPO RS. EPPO reporting service no. 09. Num. article 2017/160 First report of Popillia japonica in Switzerland. (2017).

Google Scholar

9. EPPO RS. EPPO reporting service no. 01. Num. article: 2022/010 First finding of Popillia japonica in Germany. (2022).

Google Scholar

10. EPPO RS. EPPO reporting service no. 08. Num. article: 2022/165 new finding of Popillia japonica in Germany. (2022).

Google Scholar

11. ANSES. Demande d’évaluation du risque simplifiée (ERS) lié à popillia japonica, le sacarabée japonais, pour la France métropolitaine. (Saisine 2021-SA-0090). Maisons-Alfort: Anses (2022). p. 202.

Google Scholar

12. EPPO. Decision-support scheme for an express pest risk analysis. EPPO Bull (2012) 42:457–62. doi: 10.1111/epp.2591

CrossRef Full Text | Google Scholar

13. EPPO. Decision-support scheme for quarantine pests. (2011). Available at: https://www.eppo.int/media/uploaded_images/RESOURCES/eppo_standards/pm5/pm5-03-05-en.pdf (Accessed December 1, 2022).

Google Scholar

14. Clausen CP, King JL, Teranishi C. The parasites of popillia japonica in Japan and chosen (Korea), and their introduction into the united states /. Washington, D.C: U.S. Dept. of Agriculture (1927). doi: 10.5962/bhl.title.108287

CrossRef Full Text | Google Scholar

15. King JL. The present status of the established parasites of popillia japonica Newman. J Econ. Entomol. (1931) 24:453–62. doi: 10.1093/jee/24.2.453

CrossRef Full Text | Google Scholar

16. EPPO. PM 9/21(1) Popillia japonica: procedures for official control. EPPO Bull (2016) 46 (3):543–55. doi: 10.1111/epp.12345

CrossRef Full Text | Google Scholar

17. Tayeh C, Poggi S, Desneux N, Jactel H, Verheggen F. Host plants of popillia japonica: a review. Recherche Data Gouv. (2022). doi: 10.57745/SXZNQF

CrossRef Full Text | Google Scholar

18. Jin Y, Qian H. V.PhyloMaker: an r package that can generate very large phylogenies for vascular plants. Ecography (2019) 42:1353–9. doi: 10.1111/ecog.04434

CrossRef Full Text | Google Scholar

19. IPPC Secretariat. Glossary of phytosanitary terms. international standard for phytosanitary measures no. 5. Rome: FAO on behalf of the Secretariat of the International Plant Protection Convention (2022).

Google Scholar

20. EPPO RS. EPPO reporting service no. 04. Num. article: 2022/081 Update of the situation of Popillia japonica in Italy. (2022).

Google Scholar

21. Keathley CP, Potter DA. Quantitative resistance traits and suitability of woody plant species for a polyphagous scarab, Popillia japonica Newman. en (2008) 37:1548–57. doi: 10.1603/0046-225X-37.6.1548

CrossRef Full Text | Google Scholar

22. Pires EM, Koch RL. Japanese Beetle feeding and survival on apple fruits. Biosci J (2020) 36:1327–34. doi: 10.14393/BJ-v36n4a2020-50364

CrossRef Full Text | Google Scholar

23. Borner L, Martinetti D, Poggi S. A new chapter of the Japanese beetle invasion saga: predicting suitability from long-infested areas to inform surveillance strategies in Europe. bioRxiv (2022). doi: 10.1101/2022.11.14.515960

CrossRef Full Text | Google Scholar

24. Della Rocca F, Milanesi P. The new dominator of the world: Modeling the global distribution of the Japanese beetle under land use and climate change scenarios. Land (2022) 11:567. doi: 10.3390/land11040567

CrossRef Full Text | Google Scholar

25. Kistner-Thomas EJ. The potential global distribution and voltinism of the Japanese beetle (Coleoptera: Scarabaeidae) under current and future climates. J Insect Sci (2019) 19:16. doi: 10.1093/jisesa/iez023

PubMed Abstract | CrossRef Full Text | Google Scholar

26. Zhu G, Li H, Zhao L. Incorporating anthropogenic variables into ecological niche modeling to predict areas of invasion of popillia japonica. J Pest Sci (2017) 90:151–60. doi: 10.1007/s10340-016-0780-5

CrossRef Full Text | Google Scholar

27. Kowles KA, Switzer PV. Dynamics of aggregation formation in Japanese beetles, popillia japonica. J Insect Behav (2012) 25:207–21. doi: 10.1007/s10905-011-9291-7

CrossRef Full Text | Google Scholar

28. Allsopp PG. Japanese Beetle, popillia japonica Newman (Coleoptera: Scarabaeidae): Rate of movement and potential distribution of an immigrant species. Coleopt. Bull (1996) 50:81–95.

Google Scholar

29. Fox H. The distribution of the Japanese beetle in 1930 and 1931, with special reference to the area of continuous Infestation1. J Econ. Entomol. (1932) 25:396–407. doi: 10.1093/jee/25.2.396

CrossRef Full Text | Google Scholar

30. Mondino EB, Lessio F, Bianchi A, Ciampitti M, Cavagna B, Alma A. Modelling the spread of popillia japonica Newman (Coleoptera: Scarabaeidae) from a recently infested area. entomologia (2022) 42:713–21. doi: 10.1127/entomologia/2022/1370

CrossRef Full Text | Google Scholar

31. Poggi S, Roche J, Tayeh C, Borner L, Martinetti D. Biological invasion of the Japanese beetle in continental Europe at a glance. Recherche Data Gouv. (2022). doi: 10.57745/R18NGL

CrossRef Full Text | Google Scholar

32. EPPO. Corrigendum-EPPO standard PM 5/5 (1) decision-support scheme foran express pest risk analysis. EPPO Bull (2020) 50:525. doi: 10.1111/epp.12713

CrossRef Full Text | Google Scholar

33. Straubinger FB, Benjamin EO, Venus TE, Sauer J. The economic importance of early pest control: new insights from potential Popillia japonica infestation in Europe. agriRxiv (2022) 2022:20220316785. doi: 10.31220/agriRxiv.2022.00151

CrossRef Full Text | Google Scholar

34. Nunes P, Branco M, Van Halder I, Jactel H, et al. Modelling Monochamus galloprovincialis dispersal trajectories across a heterogeneous landscape to optimize monitoring by trapping networks. Landsc Ecol (2021) 36:931–41. doi: 10.1007/s10980-020-01188-1

CrossRef Full Text | Google Scholar

35. Caton BP, Fang H, Manoukis NC, Pallipparambil GR. Quantifying insect dispersal distances from trapping detections data to predict delimiting survey radii. J Appl Entomol (2021) 146:203–16. doi: 10.1111/jen.12940

CrossRef Full Text | Google Scholar

36. Lessio F, Pisa CG, Picciau L, Ciampitti M, Cavagna B, Alma A. An immunomarking method to investigate the flight distance of the Japanese beetle. entomologia (2022) 42:45–56. doi: 10.1127/entomologia/2021/1117

CrossRef Full Text | Google Scholar

37. Torrini G, Paoli F, Mazza G, Simoncini S, Benvenuti C, Strangi A, et al. Evaluation of indigenous entomopathogenic nematodes as potential biocontrol agents against popillia japonica (Coleoptera: Scarabaeidae) in northern Italy. Insects (2020) 11:804. doi: 10.3390/insects11110804

PubMed Abstract | CrossRef Full Text | Google Scholar

38. Potter DA, Powell AJ, Spicer PG, Williams DW. Cultural practices affect root-feeding white grubs (Coleoptera: Scarabaeidae) in turfgrass. J Econ. Entomol. (1996) 89:156–64. doi: 10.1093/jee/89.1.156

CrossRef Full Text | Google Scholar

39. Szendrei Z, Mallampalli N, Isaacs R. Effect of tillage on abundance of Japanese beetle, popillia japonica Newman (Col., scarabaeidae), larvae and adults in highbush blueberry fields. J Appl Entomol. (2005) 129:258–64. doi: 10.1111/j.1439-0418.2005.00961.x

CrossRef Full Text | Google Scholar

40. Tonhasca A. Response of soybean herbivores to two agronomic practices increasing agroecosystem diversity. Agric. Ecosyst Environ (1994) 48:57–65. doi: 10.1016/0167-8809(94)90075-2

CrossRef Full Text | Google Scholar

41. Potter DA. Destructive turfgrass insects: biology, diagnosis, and control. Chelsea, Mich: Ann Arbor Press (1998).

Google Scholar

42. Potter DA, Held DW. Biology and management of the Japanese beetle. Annu Rev Entomol (2002) 47:175–205. doi: 10.1146/annurev.ento.47.091201.145153

PubMed Abstract | CrossRef Full Text | Google Scholar

43. Shanovich HN, Dean AN, Koch RL, Hodgson EW. Biology and management of Japanese beetle (Coleoptera: Scarabaeidae) in corn and soybean. J Integr. Pest Manage (2019) 10:9. doi: 10.1093/jipm/pmz009

CrossRef Full Text | Google Scholar

44. Vittum PJ, Villani MG, Tashiro H. Turfgrass insects of the united states and Canada. 2nd ed. Ithaca: Comstock Pub. Associates (1999).

Google Scholar

45. Jactel H, Bonifacio L, van Halder I, Vétillard F, Robinet C, David G. A novel, easy method for estimating pheromone trap attraction range: application to the pine sawyer beetle Monochamus galloprovincialis: Estimating pheromone trap attraction range. Agr For Entomol (2019) 21:8–14. doi: 10.1111/afe.12298

CrossRef Full Text | Google Scholar

46. Thompson RN, Cobb RC, Gilligan CA, Cunniffe NJ. Management of invading pathogens should be informed by epidemiology rather than administrative boundaries. Ecol Model (2016) 324:28–32. doi: 10.1016/j.ecolmodel.2015.12.014

CrossRef Full Text | Google Scholar

47. Carvajal-Yepes M, Cardwell K, Nelson A, Garrett KA, Giovani B, Saunders DGO, et al. A global surveillance system for crop diseases. Science (2019) 364:1237–9. doi: 10.1126/science.aaw1572

PubMed Abstract | CrossRef Full Text | Google Scholar

48. Giovani B, Blümel S, Lopian R, Teulon D, Bloem S, Galeano Martínez C, et al. Science diplomacy for plant health. Nat Plants (2020) 6:902–5. doi: 10.1038/s41477-020-0744-x

PubMed Abstract | CrossRef Full Text | Google Scholar

49. Hulme PE. Advancing one biosecurity to address the pandemic risks of biological invasions. BioScience (2021) 71:708–21. doi: 10.1093/biosci/biab019

PubMed Abstract | CrossRef Full Text | Google Scholar

Keywords: Popillia japonica, biological invasion, risk assessment, surveillance, monitoring, pest control, metropolitan France

Citation: Poggi S, Desneux N, Jactel H, Tayeh C and Verheggen F (2022) A nationwide pest risk analysis in the context of the ongoing Japanese beetle invasion in Continental Europe: The case of metropolitan France. Front. Insect Sci. 2:1079756. doi: 10.3389/finsc.2022.1079756

Received: 25 October 2022; Accepted: 25 November 2022;
Published: 12 December 2022.

Edited by:

William D. Hutchison, University of Minnesota Twin Cities, United States

Reviewed by:

Giulia Torrini, Council for Agricultural and Economics Research (CREA), Italy
Robert C. Venette, Forest Service, United States Department of Agriculture (USDA), United States

Copyright © 2022 Poggi, Desneux, Jactel, Tayeh and Verheggen. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Sylvain Poggi, c3lsdmFpbi5wb2dnaUBpbnJhZS5mcg==

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.