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Japanese beetle

The Japanese beetle (Popillia japonica Newman) is a scarab beetle native to and a highly destructive invasive pest in , , and parts of , known for its metallic green body and coppery-brown wing covers. Adults measure about 10 mm in length, with six tufts of white hairs along each side of the abdomen and two additional tufts at the rear, distinguishing them from similar species. The larvae, or white grubs, are C-shaped, cream-colored worms up to 30 mm long that primarily feed on grass and plant roots underground. First detected in Riverton, , in 1916 after likely arriving via imported nursery stock around 1911, the beetle has since spread across the eastern and central United States, reaching as far west as the and in expanding populations in western states, including where detections have increased significantly since 2021 (as of 2025). It affects over 300 plant species, with adults skeletonizing leaves, flowers, and fruits of ornamentals, turfgrasses, vegetables, and crops like corn, soybeans, grapes, and fruits, while grubs damage root systems, leading to and browning of turf. Economic losses from its feeding and the need for control measures exceed hundreds of millions of dollars annually in the U.S., particularly in and . The beetle completes one generation per year in most regions, though it may take two years in cooler northern areas. Adults emerge from the soil in late or early July, feeding voraciously for 30 to 45 days while females burrow into turf to lay up to 60 eggs in clusters. The eggs hatch in about two weeks, and the larvae feed on through three instars, overwintering deep in the as third instars before resuming feeding in spring, pupating, and emerging as adults. In its native range, natural enemies like parasites and predators limit populations, but in introduced ranges, —including cultural practices, biological controls, and targeted insecticides—is essential for mitigation.

Biology

Taxonomy

The Japanese beetle, Popillia japonica, belongs to the kingdom Animalia, phylum Arthropoda, class Insecta, order Coleoptera, family , subfamily Rutelinae, genus Popillia, and species P. japonica (Newman, 1841). The species was first described by entomologist Newman in 1841, based on specimens collected in and published in The Entomological Magazine. Earlier misattributions placed the description in 1838, but the valid publication year is 1841. Synonyms include Aserica japonica (Motschulsky), Autoserica japonica, Maladera japonica, Popillia plicatipennis (Burmeister), and Serica japonica. The genus Popillia Dejean, 1821, comprises approximately 324 , with an distribution and about 134 species in the Oriental and Palearctic regions; most are native to , but P. japonica is among the few that have become invasive outside . Within the tribe , Popillia species are characterized as shiny, metallic scarabs often associated with grassy habitats in their native ranges. Phylogenetically, P. japonica is closely related to other members of the superfamily, particularly forming a with genera like Protaetia and Rhopaea based on mitochondrial genome analyses; genetic studies using complete mitochondrial sequences from diverse populations confirm the monophyly of Popillia within Rutelinae, with strong bootstrap support (BP = 100) and (PP = 1). These studies highlight low in invasive populations compared to native ones, supporting a single origin for North American introductions. No subspecies of P. japonica are currently recognized, though minor color variations have been noted across native and invasive populations, potentially linked to environmental rather than taxonomic distinction.

Physical description

The Japanese beetle is a broadly measuring 8 to 11 mm in length and 5 to 7 mm in width, featuring a metallic green head and with coppery-brown wing covers (elytra) and an iridescent sheen that aids in identification. The abdomen displays 12 tufts of white hairs: five patches along each side and two at the rear, a diagnostic feature distinguishing it from similar scarab beetles. Sexual dimorphism is evident in size and body form, with females generally larger and possessing stouter bodies compared to males, which are slightly smaller overall. Larvae, known as white grubs, are C-shaped, creamy white bodies with a brown head capsule and three pairs of thoracic legs, reaching up to 25-30 mm in length at maturity. A distinctive raster pattern on the ventral surface of the last abdominal segment consists of two rows of short spines converging to form a V-shape, which helps differentiate Japanese beetle grubs from native scarab species. Pupae are exarate, meaning their appendages are free from the body, with a reddish-brown coloration and a of approximately 14 mm; they partially resemble the form but with wings and legs folded against the body. Eggs are small, white to creamy, oval structures about 1.5 mm in , becoming slightly more spherical as they absorb water in the .

Life cycle

The Japanese beetle (Popillia japonica) undergoes complete , progressing through four distinct life stages: , , , and . This process is typically univoltine in temperate climates, completing one generation per year, though populations in cooler regions may require two years. Adult beetles emerge from the soil in late June to early July, triggered by warming spring temperatures, and live 30 to 45 days. Upon emergence, adults engage in mating flights, with females subsequently burrowing 2 to 8 inches into the soil—preferring moist sites such as turf or mulched areas—to deposit eggs in clusters of 10 to 30. Each female lays up to 60 eggs over multiple oviposition events during her lifespan. Eggs hatch in 1 to 2 weeks, with development accelerated in warm, moist soil (approximately 8 to 9 days at 80°F to 90°F and adequate moisture for swelling). Soil moisture is critical for hatching success, as dry conditions can reduce viability. Newly hatched larvae, known as grubs, progress through three s while feeding primarily on ; the first instar lasts 2 to 3 weeks, the second 3 to 4 weeks, and the third dominates the stage at 8 to 10 months total duration. In late summer to fall, third-instar larvae burrow 4 to 20 deep into the (often 10 to 20 ) to overwinter, entering as soil temperatures drop below 60°F (15°C). This , induced by shortening day lengths and cooling temperatures, maintains dormancy through winter below the frost line. In spring, as soil temperatures rise above 50°F (10°C), larvae migrate upward to resume root feeding for 4 to 6 weeks before pupation. Mature third-instar larvae form earthen pupal chambers in the during , with the pupal lasting 1 to 3 weeks until eclosion. Pupation is environmentally cued by temperatures exceeding 50°F (10°C) following the final feeding period. Throughout the cycle, and significantly influence developmental rates, survival, and termination, with optimal conditions promoting faster progression and higher viability.

Distribution and ecology

Native range

The Japanese beetle (Popillia japonica) is native to the , encompassing the main islands of , , , and , where it has been documented since early entomological surveys. It also occurs naturally in parts of eastern , particularly and the such as , and some records indicate a possible native or ancient introduction status on the Korean peninsula. Historical observations in reveal that P. japonica is distributed across much of the country but remains at low population densities and is not regarded as an economic pest, largely due to the suppressive effects of a diverse array of natural enemies. These include predators that consume adults, soil-dwelling entomopathogenic fungi and nematodes that infect larvae, and parasitic that target various life stages, maintaining ecological balance without significant agricultural disruption. In its native habitats, the larvae of P. japonica occupy the soil in temperate grasslands, forest margins, and meadow edges, where they feed on roots of grasses and forbs, contributing to nutrient cycling while facing predation pressure. Adult beetles aggregate on flowering plants during summer, feeding on pollen, nectar, and foliage, which supports their role in pollination networks; however, populations are kept in check by parasitoids such as the tiphiid wasp Tiphia vernalis, which specifically targets and regulates third-instar grubs. The species thrives in temperate climatic conditions characterized by mild winters and moderate summers, with suitable conditions extending to elevations up to around 1,500 meters in Japan's mountainous terrain, where cooler highland environments influence developmental timing.

Introduced ranges

The Japanese beetle (Popillia japonica) was first introduced to the in 1916 near Riverton, , likely arriving as larvae in the soil associated with imported nursery stock from . This accidental introduction marked the beginning of its invasion as a significant agricultural pest outside its native range in . By the , the beetle had spread to several eastern states through human-mediated transport, including infested plant material and soil via trade and travel. In the United States, the species has since expanded to over 30 states, primarily east of the , ranging from in the north to in the south and westward to . Recent expansions have reached the Midwest and in the , driven by both natural dispersal—such as adult flight distances of up to 5 km—and human-assisted mechanisms like the movement of contaminated vehicles, equipment, and horticultural goods. Wind can also aid short-distance passive dispersal, though long-range spread is predominantly . Internationally, the beetle established in starting in the 1930s in and , with further detections in provinces like and by the late 20th and early 21st centuries. In , it was introduced to the archipelago in the 1970s and has since appeared on the mainland, with the first confirmed population near , , in 2014, followed by spread to , in 2025, and other regions. These introductions are similarly attributed to global trade in plants and soil. As of 2025, the beetle continues its westward push in the , with increased detections in states like (where trap counts nearly tripled from 2024), , , and following a 2023 infestation in Sacramento County. Climate models indicate that warming temperatures will facilitate further range expansion, particularly northward and westward, by extending suitable habitats. The species is designated a quarantine pest in non-infested areas, with the USDA's Animal and Plant Health Inspection Service (APHIS) implementing monitoring programs, including trap surveys and regulatory revisions to prevent artificial spread via aircraft and interstate commerce.

Habitat preferences and behavior

The Japanese beetle, Popillia japonica, prefers habitats characterized by moist, well-drained soils rich in , particularly in sunny, open areas such as lawns, courses, agricultural fields, and meadows. Larvae thrive in turfgrass environments where adequate supports development, as lower levels inhibit egg-laying and development, while higher moisture supports egg swelling and hatching. Adults favor sun-exposed sites, avoiding shaded regions that limit their activity and aggregation. These preferences align with the species' need for environments that facilitate both larval root-feeding in the and adult exposure to warmth and light. Adult Japanese beetles exhibit diurnal , becoming most active on warm, sunny days when temperatures exceed 70°F (21°C), during which they form feeding aggregations on foliage. These aggregations are mediated by a combination of plant volatiles from damaged leaves and the beetle's own aggregation pheromones, which draw both males and females to shared feeding sites, enhancing group efficiency. occurs in swarms triggered by the female sex pheromone japonilure, where newly emerged virgin females release the signal upon eclosion, attracting multiple males for copulation, often on the surface or low ; this process supports polygynous and polyandrous reproductive strategies. Dispersal flights typically happen in the morning, allowing adults to cover distances up to half a mile in search of suitable feeding or oviposition sites. Larval behavior centers on burrowing within the upper 10-15 cm of in root zones of grasses, where third-instar grubs feed voraciously on and , migrating deeper during dry periods or cold weather to avoid and low temperatures. These C-shaped grubs are subterranean and show negative phototaxis, remaining in darker layers to minimize exposure. Seasonal activity peaks for adults from mid-June to August in temperate regions, coinciding with summer warmth, while larvae are active from late summer through spring before pupation. Ecological interactions include predation by on eggs and early-instar larvae in turf soils, which can reduce populations but also reflects the grubs' vulnerability in open root zones. Sensory adaptations enable effective : olfactory receptors on antennae detect sex pheromones and plant volatiles over long distances, guiding mate location and oviposition, while visual cues from green foliage and movement aid in aggregation and host selection during flight. This integration of chemosensory and visual systems supports the beetle's invasive success in diverse landscapes.

Pest status

Host plants

The Japanese beetle, Popillia japonica, is highly polyphagous as an adult, feeding on foliage, flowers, and fruits of over 400 plant species across more than 90 families, with a strong preference for members of the Rosaceae (e.g., roses and apples) and Fabaceae (e.g., soybeans), as well as ornamentals such as linden and birch. Adults are attracted to these hosts primarily through kairomones and feeding-induced volatiles released from damaged leaves, which signal suitable food sources and amplify aggregation on preferred plants. In contrast, larvae exhibit non-selective feeding on roots of grasses (Poaceae family), turf, and various crop roots, showing no strong preferences and consuming decaying organic matter alongside live roots in soil. Key genera susceptible to adult feeding include:
  • Rosa (roses)
  • (apples, crabapples)
  • (linden)
  • Betula (birch)
  • (soybeans)
  • (corn)
Notably, certain invasive plants like () are avoided, likely due to unfavorable chemical or physical traits. Host plant resistance plays a role in limiting infestation, with physical traits such as hairy or pubescent leaves (e.g., in yarrow, spp.) and chemical deterrents like milky sap reducing adult feeding preference and performance. Recent genomic studies from the 2020s, including de novo genome assembly of P. japonica, have revealed expansions in odorant and gustatory receptor families, providing insights into the molecular basis for its broad host range and potential for further expansion.

Damage mechanisms

Adult Japanese beetles inflict damage primarily through foliar feeding, consuming the soft tissues between leaf veins on the upper surface of leaves, which results in a characteristic skeletonized or lace-like appearance of the foliage. This selective chewing spares the tougher veins while removing photosynthetic tissue, reducing the plant's ability to produce energy and potentially leading to severe defoliation, with up to 100% leaf loss possible in localized outbreaks where beetle densities are high. In addition to leaves, adults feed on flowers, consuming pollen and nectar, which can diminish bloom attractiveness to pollinators and reduce fruit set in affected plants. Larval stages, known as white grubs, cause subterranean damage by feeding on plant roots, beginning with fine fibrous roots and progressing to the of larger roots, which disrupts and uptake leading to symptoms such as , yellowing, and thinning of aboveground growth. In turfgrass, heavy larval feeding severs grass roots near the surface, creating brown, irregular patches that can be easily pulled up like loose due to the lack of anchorage and impaired . While larvae also consume decaying in the , contributing to , their burrowing activity compacts and reduces , exacerbating stress on root systems. Japanese beetles can indirectly facilitate secondary infections by creating feeding wounds that serve as entry points for fungal pathogens, increasing susceptibility to diseases under stressed conditions. Eggs laid in cause no direct harm as they do not feed, and pupae remain immobile in earthen cells without inflicting damage. Economic injury thresholds for defoliation in orchards are typically around 15%, beyond which significant yield reductions may occur due to lost photosynthetic capacity.

Economic and environmental impacts

The Japanese beetle (Popillia japonica) inflicts substantial economic losses, with estimates indicating annual damages of $450 million as of 2010 (likely higher in the 2020s), including impacts on agriculture, turf, and ornamentals from feeding and control efforts. As a major pest of corn, soybeans, and fruit crops, severe infestations can lead to yield reductions through extensive defoliation during critical growth stages, though recent studies on soybeans show no significant overall yield impacts despite moderate injury levels. These impacts are particularly acute in the Midwest, where beetle feeding on silks and leaves disrupts pollination and photosynthesis, exacerbating losses in staple commodities. As of 2025, surveys indicate increased populations in areas like Washington State, with trap catches nearly tripling in some locations, potentially exacerbating impacts due to milder winters. Beyond , the beetle causes significant damage to landscapes, including lawns, courses, and ornamental , with annual costs for turf replacement and remediation reaching $450-460 million across the U.S. Grubs sever roots of turfgrass, leading to widespread browning and die-off that requires costly reseeding or installation, while adults skeletonize foliage on roses, shrubs, and trees, diminishing aesthetic and property values. In urban and recreational settings, such as courses, these damages compound maintenance expenses and can render areas unusable during peak seasons. Environmentally, the invasive Japanese beetle disrupts native ecosystems by competing with pollinators for floral resources and altering microbial communities through larval burrowing and waste deposition, which decreases diversity in bacteria, fungi, and populations. As an , it outcompetes native scarab beetles for food and habitat, contributing to reduced in grasslands and pastures where root damage from grubs weakens plant stability and promotes . These effects are amplified in systems, where limited chemical options heighten vulnerability to outbreaks. Globally, the beetle's spread remains limited in due to strict quarantines and programs, though projections suggest a high potential for wider invasion into agricultural regions, posing risks to and .

Management

Cultural and physical controls

Cultural controls for Japanese beetles involve modifying agricultural and landscaping practices to disrupt the pest's and reduce population buildup without relying on chemical interventions. , particularly alternating susceptible host with non-host crops such as grains or , helps break the one-year of the beetle's grubs by denying them preferred feeding sites in the . This practice is especially effective in field crops and gardens, where rotating away from beetle-favored like roses or grapes for at least two to three years can lower larval densities. Soil management techniques further support these efforts by targeting the soil-dwelling grub stage. Deep tilling in fall or spring exposes grubs to natural predators and , while improving drainage and allowing periods of during egg-laying periods in midsummer reduces egg survival and hatch rates. In lawns, promotes deeper root growth in turfgrass, enhancing tolerance to grub feeding, and reseeding with endophyte-infected varieties of tall fescue provides additional , as the symbiotic fungi in these grasses deter larval establishment and improve plant recovery from damage. Trap cropping utilizes plants that attract adult beetles but harm them upon feeding, serving as a sacrificial barrier. Zonal geraniums ( x hortorum) are particularly effective, as their flowers contain an called that induces rapid in Japanese beetles, causing them to drop off plants for up to two hours and facilitating easy collection and disposal. Planting geraniums near vulnerable crops like roses or fruit trees can divert beetles, reducing damage to primary hosts in small-scale settings when combined with daily removal. Physical controls focus on direct mechanical intervention to limit adult access to plants. Hand-picking beetles in the early morning or evening, when they are less active, and dropping them into soapy water is a practical for home gardens and small orchards, providing effective localized through repeated sessions. Fine-mesh netting or row covers draped over susceptible plants create impenetrable barriers, preventing egg-laying and feeding while allowing light and air penetration; this approach has shown high efficacy in protecting high-value crops like grapes, with near-complete exclusion when properly installed before adult emergence. Quarantine measures enforced by regulatory agencies play a crucial role in preventing the spread of Japanese beetles through human-assisted movement. The USDA Animal and Service (APHIS) maintains a federal program that requires inspections of nursery stock, , and plant material for beetle life stages before interstate shipment, ensuring only certified pest-free materials are distributed. State-level regulations, such as those in and , complement this by prohibiting the transport of infested items and mandating treatments or certifications for exports from quarantined areas, with recent amendments to eradication programs in as of March 2025. When integrated with regular monitoring for early detection, these cultural and physical methods can promote sustainable long-term suppression of Japanese beetle populations in managed landscapes, depending on site-specific implementation and pest pressure. Recent research as of October 2025 is exploring natural plant compounds, such as those from birch leaves, to deter beetle feeding and enhance host plant resistance.

Chemical controls

Chemical controls for the Japanese beetle primarily involve synthetic insecticides targeting either the larval (grub) or adult stages, with application methods tailored to life cycle timing for optimal efficacy. Neonicotinoids such as imidacloprid are commonly applied as soil drenches or granules to control grubs, providing preventive protection by targeting eggs and young larvae before significant root damage occurs. Other effective grub-targeting options include clothianidin and trichlorfon for curative control, though these are more toxic to non-target organisms. For adult beetles, foliar sprays of or pyrethroids like and lambda-cyhalothrin are standard, offering residual protection of 1-3 weeks by killing beetles on contact or through . These insecticides disrupt function, leading to rapid knockdown, but require reapplication as new adults emerge. Application timing is critical: preventive grub treatments with or similar neonicotinoids should occur in late to early summer (mid-June to mid-July in many regions) before hatch, while curative applications target fall or early when s are actively feeding near the surface. Adult sprays are most effective during early emergence in late June to August, ideally in the afternoon when beetles are active on foliage. Baits and attractants, such as synthetic pheromones combined with floral lures, can be integrated into traps that incorporate insecticides to concentrate and kill captured adults, enhancing localized suppression though traps alone do not reduce overall populations. Insecticide resistance has emerged in Japanese beetle populations, particularly to organophosphates, necessitating rotation of chemical classes to maintain efficacy. All products must be EPA-approved for Japanese beetle use, with strict restrictions prohibiting application in certified organic areas and guidelines emphasizing pollinator safety, such as avoiding sprays on blooming plants or during bee foraging times to minimize toxicity to bees and other beneficial insects. Residue limits on food crops are enforced to protect human health. These insecticides generally provide effective control, with foliar applications achieving high mortality rates on adults and soil treatments reducing grub populations significantly, though non-target effects on pollinators and potential environmental persistence pose risks that require careful management. Recent developments include low-toxicity formulations like (Acelepryn), which offers 2-4 weeks of grub and with reduced impact on bees and has been widely adopted in eradication programs for its systemic action and EPA "reduced risk" .

Biological controls

Biological strategies for the Japanese beetle (Popillia japonica) rely on natural enemies, pathogens, and genetic interventions to suppress populations in a sustainable manner, often integrated into broader pest management frameworks. Classical biological has involved the introduction of parasitoids from the beetle's native range in . The spring tiphiid wasp Tiphia vernalis, first imported to the in the by the USDA, targets third-instar grubs by laying eggs on or near them; the wasp larvae then feed on the paralyzed , leading to its death. This parasitoid has become established in multiple eastern and midwestern states, achieving notable parasitism rates in some areas under optimal conditions. Similarly, the tachinid fly Istocheta aldrichi, also native to , was identified in the and introduced starting in the ; flies lay eggs on feeding beetles, and the larvae develop internally, causing mortality. Establishment of I. aldrichi has occurred in parts of the northeastern U.S., contributing to localized reductions in beetle numbers. Entomopathogenic organisms provide another key avenue for control, particularly against soil-dwelling grubs. The bacterium Paenibacillus popilliae, responsible for milky disease, infects Japanese beetle larvae via spores applied to turf, causing a that turns the grub's milky white and eventually kills it; this pathogen was first commercialized in the 1940s and remains effective in warmer climates where soil temperatures exceed 20°C (68°F). Field applications can significantly lower grub densities and subsequent adult emergence over 1-3 years. Fungal pathogens like Metarhizium anisopliae are used as soil treatments or foliar sprays; the fungus invades the insect cuticle under humid conditions, leading to death within 3-7 days, with lab studies showing over 80% mortality in exposed adults, though field trials indicate variable grub reduction when combined with . Nematodes, such as Heterorhabditis bacteriophora, offer targeted control of grubs through active foraging in soil; these beneficial worms enter the host via natural openings, releasing (Photorhabdus luminescens) that cause septicemia and death within 48 hours. Applications are most effective in warm soils above 18°C (65°F) and moist conditions, with high infection rates in third-instar grubs under laboratory settings and moderate efficacy in field plots. Natural predators also play a role, including birds like starlings and that consume adults, and mammals such as and moles that unearth and eat grubs; enhancements like bird feeders or reduced use can boost these populations to aid suppression. Emerging genetic methods include (RNAi)-based sprays, where double-stranded targeting essential genes like the 26S subunit is delivered via foliar application, silencing and significantly increasing adult mortality in trials. The , involving gamma radiation to sterilize males for release, has been explored since the but faces challenges in mass-rearing and competitiveness, with limited field success to date. Within (IPM) programs, these biological controls contribute to reductions in outbreak severity when layered with monitoring, as seen in long-term USDA efforts combining parasitoids and pathogens. Despite these advances, challenges persist, including temperature sensitivity—nematodes and fungi perform poorly below 15°C (59°F)—and specificity, where agents like milky disease primarily affect scarab grubs but may not persist in cooler northern regions. Additionally, variable establishment rates for introduced parasitoids due to climate mismatches limit widespread efficacy, necessitating region-specific adaptations in IPM strategies.

References

  1. [1]
    Japanese Beetle | National Invasive Species Information Center
    The Japanese beetle (Popillia japonica Newman) is a highly destructive plant pest of foreign origin. It was first found in the United States in 1916 and has ...
  2. [2]
    The Japanese beetle Popillia japonica Newman Scarabaeidae ...
    The adult Japanese beetle is ½ inch (10mm) long and metallic green with coppery-brown wing covers. They have six small white patches of hairs along each side. ...
  3. [3]
    Japanese Beetle | Animal and Plant Health Inspection Service
    Sep 26, 2025 · The Japanese beetle (Popillia japonica) is a destructive turf, grass, and plant pest. Beneath the soil, growing grubs gnaw on grass roots causing turf to brown ...
  4. [4]
    Japanese Beetle as a Pest of Field Corn - Land-Grant Press
    Feb 14, 2022 · Japanese beetle, Popillia japonica, is a generalist pest capable of feeding on over 300 different plant species, many of which are of economic ...
  5. [5]
    EENY350/IN630: Japanese Beetle, Popillia japonica Newman (Insecta
    The Japanese beetle, Popillia japonica Newman, is a widespread and destructive pest of turf, landscape, and ornamental plants in the United States.Missing: impact | Show results with:impact
  6. [6]
    [PDF] Japanese Beetle - MSU College of Agriculture and Natural Resources
    There is usually one generation per year, although a full life cycle may take two years in the coldest re- gions of Japanese beetle distribution. In Michigan,.
  7. [7]
    Time to Watch Out for the Japanese Beetle - Alabama Extension
    Jun 16, 2022 · An individual Japanese beetle lifespan is about 30 to 45 days. During the feeding period, females intermittently leave plants, burrow about 3 ...
  8. [8]
    Japanese beetles in yards and gardens | UMN Extension
    Life cycle. Japanese beetle grubs spend the winter underground in the soil of lawns, pastures, and other grassy areas. In spring, grubs move up near the soil ...
  9. [9]
    Japanese beetle (Popillia japonica Newman, 1841) - Invasive.Org
    Taxonomic Rank ; Kingdom: Animalia ; Phylum: Arthropoda ; Subphylum: Hexapoda ; Class: Insecta ; Infraclass: Neoptera.
  10. [10]
    Species Popillia japonica - Japanese Beetle - BugGuide.Net
    Genus Popillia. Species japonica (Japanese Beetle). Explanation of Names. Popillia japonica Newman 1841. Size. 9–11 mm(1). Range. native to Japan, adventive ...Missing: scientific | Show results with:scientific
  11. [11]
    Popillia japonica Pest Information - Plant Health Portal
    Taxonomy Popillia japonica. Animalia. Arthropoda. Insecta. Coleoptera. Scarabaeidae. Rutelinae. Popillia japonica. Synonym names Popillia japonica. Aserica ...
  12. [12]
    The direction, timing and demography of Popillia japonica ... - Nature
    Mar 26, 2024 · The genus Popillia Serville, 1825 includes 324 species, with an Indo-African distribution. In the oriental and palearctic region, 134 species ...
  13. [13]
    Popillia japonica - Lucid key
    The genus Popillia contains over 250 species. There is no complete identification resource for the entire genus. Popillia are members of the tribe Anomalini ...
  14. [14]
    The first complete mitochondrial genome of the Japanese beetle ...
    Phylogenetic relationships of the superfamily Scarabaeoidea show that Po. japonica and Protaetia brevitarsis form in a clade that is a sister group to Rhopaea ...
  15. [15]
    Elucidating Scarab Divergence in an Evolutionary-Ecological ... - MDPI
    Aug 3, 2024 · Within Rutelinae, the monophyly of Popillia was well verified (BP = 100, PP = 1). However, the monophyly of Anomala was questioned, as it ...Elucidating Scarab... · 3. Results · 3.3. Phylogenetic...<|separator|>
  16. [16]
    Popillia japonica (Japanese beetle) | CABI Compendium
    Popillia japonica is a minor pest because natural enemies suppress populations and the terrain is generally unsuitable for larval development.
  17. [17]
    Japanese Beetle | Ohioline
    Jan 21, 2015 · Life Cycle and Habits ... Larvae that have matured by June pupate and the adult beetles emerge from the last week of June through July. On warm ...
  18. [18]
    Japanese beetle - Agricultural Biology - CSU College of Ag Sciences
    The Japanese beetle is an invasive species in North America and native to northern Japan. In the United States, this pest is more prevalent in eastern states.
  19. [19]
    Japanese Beetle Repeatedly Eradicated from California - UC IPM
    The pupa is about 1/2 inch long and oblong. It initially is creamy white then darkens to brownish and green as it ages. Lookalikes. Adults and larvae of various ...
  20. [20]
    White Grubs in Home Lawns - Penn State Extension
    Apr 14, 2023 · Japanese beetle grubs have a V-shaped raster pattern, while northern masked chafer grubs have a nondescript "random" raster pattern (Figure 3).
  21. [21]
    Japanese Beetle - Wisconsin Horticulture
    Jul 19, 2024 · Life Cycle. Japanese beetles have only one generation per year. Adults typically begin to emerge in late June or early July around 1000 growing ...Life Cycle · Control · Landscape And Garden Plants
  22. [22]
    Japanese Beetles in the Urban Landscape - UK Entomology
    Life Cycle. Egg laying begins soon after the adults emerge from the ground and mate. Females leave plants in the afternoon, burrow 2 to 3 inches into the ...
  23. [23]
    https://entomology.mgcafe.uky.edu/ef451
  24. [24]
    Japanese Beetle : Landscape - UMass Amherst
    Jan 5, 2023 · First instar grubs feed for 2-3 weeks, then molt and feed again. Three to four weeks later, the second instars molt into third instars. Most ...Identification/life Cycle · Monitoring · Cultural/mechanical...Missing: durations factors
  25. [25]
    [PDF] Japanese Beetle: Insect Pest of Horticultural Plants and Turfgrass
    Japanese beetle has a one-year life cycle consisting of an egg, larva or grub, pupa, and adult (Figure 1). Japanese beetle adults are ⅜ to ½ inch (10 to 13 mm) ...
  26. [26]
    Modelling diapause termination and phenology of the Japanese ...
    Sep 20, 2021 · ... larval diapause termination and for the development rate function ... The Japanese beetle (Popillia japonica) is an invasive and highly ...
  27. [27]
    [PDF] Managing the Japanese Beetle: A Homeowner's Handbook
    In early spring, the grubs return to the turf and continue to feed on roots until late spring, when they change into pupae. In about 2 weeks, the pupae become ...
  28. [28]
    Japanese beetle in vegetables - Agricultural Biology
    Activity resumes the following spring once soil temperatures reach 10°C (50°F). The mature larvae begin to pupate in earthen cells after feeding for 4-8 weeks, ...
  29. [29]
    Biology and Management of Japanese Beetle (Coleoptera
    Apr 15, 2019 · The development and survival of newly hatched larvae are greatly dependent on soil moisture and temperature, with larvae being susceptible ...
  30. [30]
    Popillia japonica | Hawaiian Scarabs - IDtools
    Common name(s). Japanese beetle. Taxonomy. Family: Scarabaeidae Subfamily: Rutelinae Genus: Popillia Species: Popillia japonica Newman, 1838. DNA barcode. DNA ...
  31. [31]
    [PDF] Popillia japonica
    Popilia japonica is a polyphagous species, feeding on at least 295 species of plants. Acer, Malus, Prunus, Rosa, Rubus,. Vitis and Zea mays are the main host ...
  32. [32]
    Popillia Japonica (Japanese Beetle) - Fact Sheet - Canada.ca
    Jun 28, 2023 · Distribution. Asia: China, India (unconfirmed), Japan, Korean peninsula (unconfirmed) and Russia; North America: USA and Canada. The Regulatory ...
  33. [33]
    [PDF] BIOLOGY AND MANAGEMENT OF THE JAPANESE BEETLE
    JB larvae, like adults, are polyphagous (46), but they tend to occur as facultative monophages because their limited mobility restricts them to plant roots ...
  34. [34]
    Survey of Tiphia Vernalis (Hymenoptera: Tiphiidae), a Parasitoid ...
    Dec 1, 2007 · In its native habitat (Korea, Japan, and China), T. vernalis has been reported to parasitize P. quadriguttata (Fabricius), P. chinensis ...
  35. [35]
    The Potential Global Distribution and Voltinism of the Japanese ...
    Mar 22, 2019 · In its native Japan, P. japonica is regarded as a minor agricultural pest, which is probably because much of Japan's terrain is not suitable for ...
  36. [36]
    Study area. (A) Light/dark red indicates low/high elevation (m a.s.l.),...
    This study focused on modelling the current and projected distribution of the Japanese beetle (Popillia japonica Newman), an invasive pest with potentially ...
  37. [37]
    Potential distribution and spread of Japanese beetle in Washington ...
    Jun 15, 2023 · The short-distance dispersal simulations show Japanese beetles could spread and occupy most habitat in central-southern Washington within 20 ...
  38. [38]
    (PDF) Factors influencing the capture of Japanese beetles: wind ...
    Fifty-two percent of 667 JB observed flew directly upwind toward a trap with a dual lure (sex pheromone + floral kairomone), especially when wind speed exceeded ...Missing: assisted | Show results with:assisted
  39. [39]
    Tracing the dispersal route of the invasive Japanese beetle Popillia ...
    Jun 26, 2023 · Genetic analyses of Japanese samples of P. japonica identified two different lineages in the native area, the first in Kyushu and Tsushima and ...Missing: genus | Show results with:genus
  40. [40]
    From lab to field: biological control of the Japanese beetle ... - Frontiers
    May 9, 2023 · It was accidentally introduced to the USA in the beginning of the 20th century (4) and spread from New Jersey to the west coast, up to Canada, ...
  41. [41]
    https://www.ages.at/en/plant/plant-health/pests-from-a-to-z/japanese-beetle
  42. [42]
    2023 JB Project Decisions - Japanese Beetle - CDFA - CA.gov
    2023 JB Project Decisions · One JB adult detected in high risk trapping in 2022 · 25 traps per square mile beginning May 1, 2023 (standard high hazard density).
  43. [43]
    Climate and human-modified landscapes influence spread of ...
    Sep 26, 2025 · For this study, we examine habitat associations of Japanese beetles, Popillia japonica, and predict their occurrences along the invasion front ...Missing: elevation | Show results with:elevation
  44. [44]
    APHIS Announces Final Environmental Assessment and Finding of ...
    APHIS Announces Final Environmental Assessment and Finding of No Significant Impact for Revision of the Japanese Beetle Domestic Quarantine Regulations ... 2025, ...
  45. [45]
    Japanese Beetle Program: Airport Regulatory Status - usda aphis
    View the following table for regulated and deregulated airports for Japanese beetle. Table Updated: August 27, 2025 ... Plant Protection and Quarantine ...
  46. [46]
    Soil moisture and soil texture preferences of Popillia japonica
    It was found that in choice tests no eggs were laid when the soil moisture is lower than 5% and more eggs were laid the wetter the soil, ...
  47. [47]
    Japanese Beetle - CSU Extension - Colorado State University
    Jun 1, 2007 · Japanese Beetle Life History. Japanese beetle has a one-year life cycle. Adults may begin to emerge from the soil in early June and are ...
  48. [48]
    Japanese Beetle - MSU Extension | Montana State University
    However, females will lay eggs in a wide variety of soil textures. To complete development, the eggs require sufficient moisture from the soil. Eggs hatch ...
  49. [49]
    Japanese Beetle Identification, Habits & Behavior | Russell's Pest ...
    These beetles are especially common on roses, beans, grapes, and raspberries. Japanese beetles have a voracious appetite and are most active on warm sunny days, ...
  50. [50]
    Japanese Beetles Are Back! | Extension Entomology - K-State Blogs
    Jul 6, 2017 · Moreover, Japanese beetle adults produce aggregation pheromones that attract individuals (both males and females) to the same feeding location.Missing: behavior | Show results with:behavior
  51. [51]
    Ant Predation on Eggs and Larvae of the Black Cutworm (Lepidoptera
    Aug 7, 2025 · Predation on implanted Japanese beetle eggs also tended to be greater in roughs than in fairways, and fewer grubs were found in areas of golf ...
  52. [52]
    Chiral discrimination of the Japanese beetle sex pheromone ... - NIH
    Jun 25, 2008 · The sophistication of the insect olfactory system is elegantly demonstrated by the reception of sex pheromone by the Japanese beetle.Missing: adult | Show results with:adult<|separator|>
  53. [53]
    Habits and Traits of Japanese Beetles, Popillia japonica - ThoughtCo
    Nov 20, 2019 · Popillia japonica inhabits forests, meadows, fields, and gardens. Japanese beetles even find their way to urban backyards and parks. Range:.
  54. [54]
    Exploring the main factors influencing habitat preference of Popillia ...
    Less acidic soils, especially with sandy-skeletal particles, are preferred. A high density of P. japonica larvae is associated with medium content of soil ...
  55. [55]
    A nationwide pest risk analysis in the context of the ... - Frontiers
    Dec 11, 2022 · 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 ...
  56. [56]
    https://www.sciencedirect.com/science/article/abs/pii/S1574954122001996
  57. [57]
    [PDF] Japanese Beetle Host Plant List - CDFA
    JAPANESE BEETLE HOST PLANT LIST. 7/21/2011. Scientific Name. Common Name. Abutilon theophrasti. Velvetleaf. Acalypha virginica. Three-seed. Acer palmatum.Missing: kudzu Pueraria<|control11|><|separator|>
  58. [58]
    Quantitative Resistance Traits and Suitability of Woody Plant ...
    This study evaluated adult Japanese beetles' feeding preference and performance on foliage of selected woody plant species historically rated as either ...
  59. [59]
    [PDF] Plants Resistant to Adult Japanese Beetle Feeding - usda aphis
    Plants Resistant to Adult Japanese Beetle Feeding*. Woody Plants. 1. Red maple. Acer rubrum. 2. Boxwood. Buxus spp. 3. Hickory. Carya spp. 4. Redbud.
  60. [60]
    De novo assembly and annotation of Popillia japonica's genome ...
    Mar 13, 2024 · The analysis of GRs in P. japonica identified a total of 53 putative GRs encoded by 51 different genes plus two splice variants. Among the ...Missing: genus | Show results with:genus
  61. [61]
    Japanese beetle - Biocontrol, Damage and Life Cycle - Koppert
    The pupa, which is approximately 14 mm long and 7 mm wide, resembles the adult beetle, except the wings and other appendages are closely folded to the body. It ...
  62. [62]
    Food Web Responses to Augmenting the Entomopathogenic ...
    ... feeding first on fibrous roots and later on the cortex of major roots. ... Persistence of control of Japanese Beetle (Coleoptera: Scarabaeidae) larvae with ...<|separator|>
  63. [63]
    Japanese Beetle Control - Keyman Lawn, Tree & Pest
    This loss of foliage stresses plants, making them susceptible to secondary issues like fungal infections and drought stress.
  64. [64]
    Japanese Beetle in Fruit Crops: Overwintering Survival & Updates ...
    Jul 11, 2019 · We found a wide range in beetle density and defoliation levels, but the higher defoliation levels were limited to 15-18%.
  65. [65]
    Effects of feeding injury from Popillia japonica (Coleoptera
    Oct 20, 2022 · Defoliation caused by insect feeding is a common injury seen in soybean fields that can potentially lead to yield losses due to the reduction of ...<|separator|>
  66. [66]
    Japanese Beetles: The Return of the Pest - LEAF
    Jul 15, 2025 · Economic Impacts – Adult beetles feed heavily on agricultural crops including soybeans, corn and fruit trees. This feeding reduces crop yields ...
  67. [67]
    UAH researcher gains $95K USDA grant to help control Japanese ...
    Sep 9, 2025 · UAH researcher gains $95K USDA grant to help control Japanese beetle that causes $450M in U.S. damage annually. SEP 09, 2025 | Russ Nelson. A ...
  68. [68]
    [PDF] Japanese Beetle, Popillia japonica Newman (Insecta: Coleoptera
    Adult Japanese beetles feed on foliage, flowers, and fruits. Leaves are typi- cally skeletonized or left with only a tough network of veins. The larvae, ...
  69. [69]
    The University of Alabama in Huntsville - Facebook
    Sep 11, 2025 · Japanese beetles cause an estimated $450 million in damages each year to private lawns and golf courses in the U.S.🪲 Now, a new research effort ...Missing: 2020s | Show results with:2020s
  70. [70]
    [PDF] influence of japanese beetle larvae on soil microbial diversity and ...
    PLFA analysis indicated that soil microbial diversity decreased as JB larval increased (Figure 1) with populations of rhizobia, fungi and protozoa decreasing ...Missing: native | Show results with:native
  71. [71]
    Japanese Beetle - Invasive Species Centre
    These eggs can appear white, creamy, or even translucent in colour and are originally elliptical in shape but become larger and more spherical as they mature.
  72. [72]
    A greener way to protect plants from invasive Japanese beetle
    Oct 8, 2025 · These shimmering pests skeletonize leaves, leaving only delicate veins behind. Their grubs feast on turfgrass roots, damaging lawns and fairways ...
  73. [73]
    [PDF] Japanese Beetle Integrated pest management analysis - CDFA
    Cultural controls involve the manipulation of cultivation practices to reduce the ... Biological Control of Japanese Beetle in Michigan through Parasite and.
  74. [74]
    Organic Management Options for the Japanese Beetle at Home ...
    Jan 24, 2018 · Cultural Controls​​ In agricultural settings Japanese beetles numbers can be reduced by tillage, groundcovers and, to some extent, by managing ...Missing: efficacy | Show results with:efficacy
  75. [75]
    [PDF] Japanese Beetle
    Cultural Controls. – Promotion of root growth to tolerate larval feeding. – Allowance of some soil drying during critical JB life stages.
  76. [76]
    Insect management | Cornell Turfgrass Program
    Endophyte-enhanced grasses (e.g., some perennial ryegrass and tall fescue) may be more tolerant of drought stress and recover more quickly from grub damage even ...
  77. [77]
    Geraniums Could Help Control Devastating Japanese Beetle
    Mar 8, 2010 · Geraniums may hold the key to controlling the devastating Japanese beetle, which feeds on nearly 300 plant species and costs the ornamental plant industry $450 ...
  78. [78]
    Rare excitatory amino acid from flowers of zonal geranium ...
    Jan 4, 2011 · The Japanese beetle (JB), Popillia japonica, exhibits rapid paralysis after consuming flower petals of zonal geranium, Pelargonium x hortorum.
  79. [79]
    Japanese Beetles | Extension | West Virginia University
    Jul 15, 2022 · Mechanical/Physical Control of Japanese Beetle. Hand removal can be an effective method for small-scale control of Japanese beetles. Beetles ...
  80. [80]
    Plant Health - Japanese Beetle Regulations - CDFA - CA.gov
    Section 3280, Japanese Beetle Exterior Quarantine - Inspections for Compliance. This amendment is to help prevent the artificial spread of Japanese beetle from ...
  81. [81]
    Japanese Beetles in the Home Garden - Penn State Extension
    Jun 22, 2023 · As adults, they are aggressive pests of both agricultural and ornamental plants. As larvae, the white grubs are pests of grasses in pastures and ...
  82. [82]
    Management of Adult Japanese Beetles for Commercial Nursery ...
    Carbaryl provides 1- 2 weeks of protection and pyrethroids 2-3 weeks. Protection is due to the residual insecticide that remains on leaves. This kills or ...
  83. [83]
    Managing Japanese beetles in fruit crops - MSU Extension
    Jul 12, 2011 · Their emergence during mid-summer can also result in their presence during harvest of some fruit crops, creating a risk of contamination. They ...Making Your Farm Less... · Short Phi And Organic... · Soil-Applied InsecticidesMissing: dispersal | Show results with:dispersal
  84. [84]
    How to choose and when to apply grub control products for your lawn
    May 22, 2020 · Products containing imidacloprid, thiamethoxam, clothianidin or chlorantraniloprole will not control grubs in the spring. They are preventive ...
  85. [85]
    Tips for Japanese Beetle Control
    The reduced-risk pesticides neem, Pyola (a blend of pyrethrin and canola oil) and spinosad will kill adult beetles, but only for about 3-7 days. Neem products ...Missing: pyrethroids | Show results with:pyrethroids<|separator|>
  86. [86]
    https://www.canr.msu.edu/news/managing_japanese_beetles_in_fruit_crops
  87. [87]
    Management Strategies for Private Property Owners
    Always read and follow pesticide label directions. Many of the insecticides that control Japanese beetle are also highly toxic to bees and other pollinators.
  88. [88]
    [PDF] Proclamation of Emergency Program for the Japanese Beetle - CDFA
    Jun 11, 2024 · June 2024 update​​ A systemic insecticide containing either chlorantraniliprole or imidacloprid is used to control developing larvae, and a ...<|control11|><|separator|>
  89. [89]
    Spring Tiphia (Tiphia vernalis) | NYSIPM Biocontrol Fact Sheet
    Spring Tiphia can be found outdoors anywhere Japanese beetles are present, in rural and urban areas, in gardens and on farms, as well as in the landscape.
  90. [90]
    [PDF] Assessment of Biocontrol Possibilities for Japanese Beetle
    Sep 1, 2020 · USDA has supported biocontrol efforts against Japanese beetle since 1920, importing 49 natural enemies of Japanese beetle and related ...Missing: classical Istria
  91. [91]
    Classical biological control of Japanese beetle - CABI.org
    This project is aiming to tackle the spread of the Japanese beetle by exploring the use of the parasitic fly, Istocheta aldrichi, as a classical biological ...Missing: Tiphia vernalis Istria
  92. [92]
    Paenibacillus popilliae - Biological Control
    The term "milky disease" comes from the larva's pure white appearance when infected with B. popilliae. B. popilliae was the first insect pathogen to be ...
  93. [93]
    Paenibacillus popilliae (milky disease of insects) | CABI Compendium
    Milky disease has given outstanding control of the Japanese beetle, Popillia japonica, in the warmest regions of its range since the disease was first found ...
  94. [94]
    From lab to field: biological control of the Japanese beetle with ... - NIH
    Under laboratory conditions, several fungal strains (Metarhizium spp. and Beauveria spp.) have proven successful in infecting and killing Japanese beetle larvae ...Missing: secondary | Show results with:secondary
  95. [95]
    Heterorhabditis bacteriophora, Beneficial Hb Nematode
    Heterorhabditis bacteriophora is a tiny, lethal, insect-killing nematode that attacks caterpillars, immature beetles, and white grubs. It does not harm plants ...
  96. [96]
    Can beneficial nematodes help control Japanese beetles?
    Aug 9, 2020 · “Heterorhabditis bacteriophora (Hb) nematodes are most effective against Japanese beetles, European chafers, and other grubs that are lawn pests ...<|separator|>
  97. [97]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC10926434/
  98. [98]
    Sterilization of Japanese Beetles by Gamma Radiation13
    Sterilization of Japanese Beetles by Gamma Radiation13 ... Rearing methods of four insect species intended as feed, food, and food ingredients: a review.