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Small hive beetle

The small hive beetle (Aethina tumida Murray), a member of the family Nitidulidae (sap beetles), is a parasitic insect native to sub-Saharan Africa, where it occasionally infests colonies of African honey bees (Apis mellifera scutellata) but causes minimal damage due to the bees' effective defensive behaviors.^[1] Adults are oval-shaped, measuring 5–7 mm in length and 3–4.5 mm in width, with a reddish-brown to black coloration, short elytra that expose abdominal segments, and clubbed antennae; they are highly mobile and capable of flying several kilometers to locate hives.^[1] Since its accidental introduction outside Africa—first detected in Florida, USA, in 1998—this species has become a major invasive pest of European honey bee (A. mellifera) colonies in regions including North America (including Alaska, detected in 2025), Australia, parts of Central America, and isolated outbreaks in Europe (such as Italy in 2014, where containment efforts have limited spread).^[2]^[3] The life cycle of A. tumida is closely tied to honey bee hives, with adults entering colonies attracted by hive odors and pheromones, often hiding in cracks during the day to avoid bee aggression.^[1] Females lay up to 1,000–2,000 translucent white eggs (1.4 mm long) during their lifetime, typically in small clusters of 10–30 in hive crevices or combs, which hatch in 2–3 days at temperatures of 24–34°C into light-yellow larvae that grow to about 10–11 mm while feeding voraciously on honey, pollen, and bee brood.^[1] After 10–14 days, mature larvae exit the hive, burrow 4–8 cm into nearby soil to pupate for 15–33 days (longer in cooler conditions), emerging as adults that can live 6–16 months and overwinter in hives or soil.^[1] A symbiotic yeast, Kodamaea ohmeri, associated with the beetle, aids larval digestion of hive products and produces volatile compounds that further attract adults to infested hives.^[1] Infestations by A. tumida cause significant damage through direct feeding and secondary effects: larvae tunnel through comb, consuming stores and brood while defecating and producing a fermenting "slime" that spoils honey with a characteristic rotten orange odor, often leading to colony absconding or collapse in severe cases.^[1] In non-native regions, European honey bees lack the robust grooming and hive-sealing defenses of African subspecies, exacerbating the pest's impact and resulting in economic losses estimated at millions of dollars annually for beekeepers, including costs for treatment and lost productivity.^[1] Management relies on integrated approaches such as mechanical traps (e.g., oil pan traps inside hives), soil treatments with lime or entomopathogenic nematodes to target pupae, and cultural practices like maintaining strong colonies and prompt hive sanitation; ongoing research explores biological controls like Bacillus thuringiensis and RNA interference for sustainable suppression.^[1]

Taxonomy and description

Taxonomy

The small hive beetle is scientifically classified as Aethina tumida Murray, 1867, within the order Coleoptera and family Nitidulidae.^[4] This species was first described by British entomologist Andrew Murray in 1867, based on specimens collected from South Africa, establishing its binomial nomenclature without recorded synonyms.^[5]^[6] The family Nitidulidae, known as sap beetles, encompasses around 4,500 species globally, characterized by their small size, oval bodies, and feeding habits on plant sap, decaying fruits, and fungi; A. tumida fits this profile as a member adapted to scavenging in honey bee hives.^[7] Within Nitidulidae, the genus Aethina Erichson belongs to the subfamily Nitidulinae and comprises approximately 30 species, primarily restricted to the Afrotropical region, distinguished by their compact form, clubbed antennae, and elytra with specific punctation patterns that differentiate them from related genera like Carpophilus.; recent studies have described additional species, including two new ones from China in 2024.^[8]^[9]^[10] Phylogenetically, A. tumida originates from sub-Saharan Africa, as evidenced by mitochondrial DNA analyses showing its native haplotypes clustered within African Nitidulidae lineages, with the genus Aethina positioned in the Nitidulinae clade based on molecular phylogenies of the family.^[11]^[12]^[13]

Physical characteristics

The small hive beetle, A. tumida, exhibits distinct morphological features across its life stages that aid in identification. Adults are oval-shaped beetles measuring 5–7 mm in length and 3–4.5 mm in width, ranging from light brown or yellowish shortly after emergence to dark brown or black with age.^[14] They possess club-shaped antennae, a shield-shaped thorax, broad and flattened legs adapted for movement within hives, and elytra that do not fully cover the abdomen apex, leaving the posterior exposed.^[15] The pronotum features sharp postero-lateral angles, a key diagnostic trait.^[14] Sexual dimorphism is subtle, with females slightly longer than males, and sex can be determined by gently squeezing the abdomen to reveal the female's ovipositor or the male's eighth tergite.^[14] Larvae are elongate, worm-like, and C-shaped when mature, reaching up to 10–12 mm in length and about 1.6 mm in width, with a light beige body and brown cephalic capsule.^[15]^[14] They have three pairs of thoracic legs and rows of two dorsal spines per body segment, which are more prominent on the terminal segments; unlike wax moth larvae, they lack pseudopods.^[14] Pupae are exarate, measuring around 5 mm in length and 3 mm in width, initially whitish but darkening to reddish-brown or dark brown as development progresses.^[14] They form in soil chambers and resemble the adult form in structure. For differentiation from similar species, A. tumida adults are much smaller (5–7 mm) than the large hive beetle Oplostomus fuligineus (20–23 mm long, uniformly black with orange antennal tips), and they lack the fully covering elytra and loose antennal clubs of Cychramus luteus or the orange legs and partial orange elytra of Carpophilus lugubris.^[17]^[14]

Distribution and habitat

Native range

The small hive beetle, Aethina tumida, is endemic to sub-Saharan Africa, where its primary native range spans from South Africa in the south, northward to Sudan, and westward to Angola, encompassing diverse habitats across the region.^[18] This distribution reflects its long-standing presence as a natural component of African ecosystems, with records indicating widespread occurrence in countries including Kenya, Nigeria, Tanzania, Zambia, and the Democratic Republic of Congo.^[19] In its native habitats, the beetle is closely associated with wild colonies of the African honey bee, Apis mellifera scutellata, acting primarily as a scavenger rather than a dominant parasite.^[4] These bees' natural cavity-nesting behaviors and aggressive defensive responses help maintain low beetle populations within healthy colonies, allowing coexistence without widespread disruption.^[20] Historical records from the pre-1990s, including the seminal study by Lundie (1940) in South Africa, confirm the beetle's endemic status as an occasional and minor pest, with no evidence of significant economic impact on beekeeping or wild populations prior to its global spread.^[21] Early observations noted its presence in apiaries and wild hives but emphasized limited damage compared to its invasive behavior elsewhere. Within this native range, the beetle's spread and infestation levels are constrained by environmental factors, including predation by ground-dwelling ants such as Pheidole megacephala, which targets migrating larvae, and climatic conditions like soil moisture and temperature thresholds that affect pupation success.^[22] Additionally, the robust hygiene and swarming tendencies of A. m. scutellata further mitigate severe outbreaks, preventing the beetle from overwhelming strong colonies.^[23]

Invasive spread

The small hive beetle (Aethina tumida) was first detected outside its native African range in a commercial apiary in Florida, USA, in May 1998, marking the initial invasive introduction to North America.^[4] From there, it rapidly spread across the southeastern United States, reaching states like Georgia, South Carolina, and Texas by the early 2000s, and eventually establishing populations in nearly all U.S. states (including a detection in Alaska in September 2025 from imported bee packages), Canada, and parts of Mexico and Central America.^[24]^[25] In Europe, the first confirmed incursion occurred in Italy's Calabria region in September 2014, followed by detections in Sicily, prompting immediate eradication efforts that have contained the pest to southern Italy without widespread establishment.^[26] The beetle reached Australia in 2002, where it became established in eastern states, and has since been reported in Asia, including establishment in the Philippines since 2012, and a sporadic detection in Portugal in 2004 that was eradicated (Portugal is in Europe).^[27]^[4] Human activities have been the primary vectors for this invasive spread, particularly through the international trade and movement of honey bee packages, contaminated beekeeping equipment, and swarming bee colonies.^[28] Migratory beekeeping practices, which involve transporting hives across long distances, have facilitated rapid dissemination within continents, as beetles can survive in transit and infest new apiaries upon arrival.^[29] Natural flight dispersal contributes locally but is insufficient for intercontinental jumps, underscoring the role of anthropogenic pathways.^[30] In response, regulatory measures were swiftly implemented by the USDA in the late 1990s, including federal quarantines on interstate movement of bees and equipment from infested areas, along with enhanced import inspections to prevent further introductions.^[31] The European Union followed suit in the 2000s with strict biosecurity protocols, such as prohibiting imports of package bees from non-EU countries (except New Zealand) and mandating surveillance in high-risk zones; following the 2014 Italian outbreak, EU Implementing Decisions established protection and surveillance zones, leading to the destruction of infested apiaries and restrictions on bee product trade from affected regions.^[32] Similar national quarantines were enacted in Australia and other invaded countries to limit expansion. As of 2025, containment efforts in southern Italy remain focused on Calabria and Sicily, with no new outbreaks reported since 2019 and ongoing monitoring via sentinel hives and protection zones upholding EU restrictions.^[26] In the United States, the beetle has been reported in Oregon since the early 2020s but has not caused significant colony losses, indicating potential but unconfirmed establishment in the Pacific Northwest.^[33] Recent studies highlight spatiotemporal variation in infestation levels, with higher densities observed in shaded apiaries compared to sun-exposed ones, influenced by host colony strength and environmental factors rather than management practices alone.^[34]

Preferred habitats

The small hive beetle (Aethina tumida) thrives in warm, humid environments, with optimal temperatures ranging from 28°C to 32°C for successful development and reproduction.^[35] High relative humidity levels exceeding 60% are preferred, as lower humidity impedes egg hatching and overall survival.^[11] For pupation, the beetle requires moist soil with 6–8% water content, favoring uncompacted sandy loam types that allow easy burrowing.^[35] Pupation typically occurs at depths of 4–20 cm in the soil surrounding host sites.^[14] The beetle is primarily associated with honey bee (Apis mellifera) hives in apiaries or wild nests, where it exploits the humid, food-rich interior for feeding and oviposition.^[14] Secondary habitats include fruit orchards, where adults may feed on decaying fruits as a non-host resource, and compost piles or worm farms, which provide suitable moist organic matter for temporary refuge and reproduction.^[36] These preferences align with its native African savanna origins, where such conditions are prevalent near bee colonies.^[14] In invasive ranges, the small hive beetle has shown adaptability to temperate zones by overwintering in honey bee clusters, which provide insulated warmth during cold periods.^[37] Additionally, pupation success in greenhouse substrates like coconut fiber and stone wool enables establishment in controlled indoor apiaries or pollination facilities in cooler climates.^[38] Climate change models project expanded habitat suitability for the beetle, with warming temperatures facilitating northward spread into southern Europe and North Africa by 2050 under moderate emission scenarios.^[39] A 2021 analysis using maximum entropy algorithms indicated increased risk in previously marginal areas due to prolonged warm seasons.^[39]

Life cycle

Eggs

The eggs of the small hive beetle, Aethina tumida, are tiny, translucent white, and elongated in shape, measuring approximately 1.4 mm in length and 0.26 mm in width.^[1] They are laid in clusters typically ranging from 10 to 40 eggs, which helps protect them from detection by honey bees within the hive environment.^[1] Females preferentially oviposit in protected sites such as cracks and crevices within the hive structure or directly into honey bee brood cells, often by puncturing the cell cappings to deposit eggs alongside or on developing bee pupae.^[1] Oviposition begins soon after mating, with fertilized females capable of laying up to 1,000 eggs over their lifetime, though some estimates suggest a potential upper limit of 2,000 under optimal conditions.^[1] This behavior is influenced by female guarding strategies to minimize predation by bees, as detailed in studies on parental care.^[40] The incubation period for A. tumida eggs typically lasts 2 to 3 days under hive-like conditions, such as temperatures around 34°C and high humidity, which are critical for successful embryonic development and preventing desiccation.^[1] At lower temperatures, such as 24–28°C, incubation extends to about 3 days, while overall hatching can range from 1 to 6 days depending on environmental factors. Upon hatching, triggered primarily by sufficient hive humidity, the larvae emerge from the eggs and rapidly disperse to locate suitable resources within the colony.^[1] This quick transition ensures minimal exposure time for the vulnerable egg stage in the competitive hive setting.^[1]

Larvae

The larval stage of the small hive beetle (Aethina tumida) begins upon hatching from eggs laid within honey bee hives, typically within 2–6 days under warm conditions. Newly hatched larvae measure approximately 1–1.5 mm in length and are cream-colored, elongated grubs with three pairs of thoracic legs and rows of small spines along their dorsal surface. They undergo three instars during development, progressively molting as they grow to a maximum length of about 10–11 mm by the final instar. The duration of the larval stage varies with temperature and food availability, ranging from 5–25 days overall, with optimal development occurring around 34°C where maturation can complete in as little as 10–14 days.^[41]^[27]^[42]^[43] During this stage, larvae are voracious feeders, tunneling through comb to consume honey, pollen, stored bee brood, and even adult bees if necessary. Larvae are associated with the symbiotic yeast Kodamaea ohmeri, which aids in digesting hive products and contributes to slime production. Their feeding activity not only directly damages hive resources but also produces copious frass—fine, granular excrement—that mixes with honey and pollen, initiating yeast fermentation and creating a characteristic "hive slime," a viscous, foul-smelling mess that further degrades the colony structure and discourages bee activity. This slime production is a key indicator of heavy infestation, as larvae can rapidly overwhelm hives under favorable conditions. Recent 2025 studies from the University of Georgia's Integrated Pest Management program highlight the rapid larval growth under typical hive conditions, completing development in 10–14 days at optimal temperatures (around 34°C), with significant growth visible within the first week.^[44]^[41]^[45]^[46]^[45]^[43] Upon reaching maturity in the final instar, larvae cease feeding and enter a wandering phase, exiting the hive en masse to burrow 5–15 cm into nearby soil for pupation. This dispersal behavior helps evade hive defenses and predators while preparing for the pupal stage. In temperate regions with extended warm periods, small hive beetle populations can complete up to five generations per year, largely driven by the efficiency of larval development.^[46]^[45]^[43]

Pupae

The pupal stage of the small hive beetle (Aethina tumida) begins after mature larvae exit honey bee colonies, typically at dusk, and burrow into the soil to form pupation chambers. These wandering larvae seek out moist, sandy soils near hives, often within 1 meter but potentially up to 200 meters away, preferring sites with adequate vertical space for burrowing.^[47]^[35] Larvae construct smooth-walled earthen cells 5–20 cm deep, using a saliva-like secretion to line the cavity, which provides protection during the non-feeding transformation process.^[27]^[48] The pupa is exarate, with legs and wings free from the body, initially appearing pearly white with characteristic thoracic and abdominal projections; as development progresses, it darkens to light tan or reddish-brown, reaching approximately 5 mm in length.^[44]^[47] During this vulnerable stage, the pupa does not feed and is susceptible to predation by soil invertebrates, such as ants and nematodes, which can significantly reduce survival rates in natural settings.^[49]^[35] Pupation duration varies with environmental factors, typically lasting 15–33 days, with 15–21 days at temperatures of 25–35°C under optimal moist soil conditions; cooler temperatures (below 20°C) can extend this to 25–50 days or more, while excessive heat above 35°C inhibits successful development.^[48]^[35]^[47] In suboptimal cooler conditions, development may slow considerably, though true diapause has not been widely documented. Soil moisture and type also influence the process, with drier or denser soils prolonging pupation and reducing emergence success.^[47]^[35] Upon completion of pupation, adults eclose within the soil cell and remain underground for 1–2 days to sclerotize and harden their exoskeleton, after which they emerge to seek out new hosts.^[48]^[50] This teneral phase renders newly emerged adults fragile and flightless until fully hardened.^[48]

Adults

Adult small hive beetles (Aethina tumida) exhibit a lifespan of 4–6 months on average in the wild, up to 16 months under optimal conditions.^[1] These adults are strong fliers, with dispersal ranges typically spanning 4 to 8 km, though studies have documented recaptures up to 12 km after one week.^[28] Their daily activity peaks at dusk, when they are most likely to exit and enter hives or seek new colonies.^[27] Physiologically, adult females demonstrate high fecundity, capable of laying up to 2,000 eggs over their lifetime, often in batches within honey bee hives. The yeast Kodamaea ohmeri produces volatile compounds that attract adults to infested hives.^[51] Adults overwinter primarily within bee clusters in hives, where they conserve energy by stealing heat from the bees, though some may survive in surrounding soil under favorable conditions.^[52] Post-emergence, females rapidly initiate reproduction following mating, contributing to quick population buildup in suitable environments.^[53] The beetles' antennae are highly sensitive to hive volatiles, such as those emitted by honey, pollen, and bee pheromones, enabling precise location of host colonies from a distance.^[1] Regarding population dynamics, 2025 studies indicate that infestations exceeding 10 adults per hive signal elevated risk of larval outbreaks and colony stress.^[43] Mating typically begins shortly after emergence, leading into aggregation behaviors in infested hives.

Behavior and reproduction

Feeding behavior

Adult small hive beetles (Aethina tumida) exhibit opportunistic foraging behavior, primarily targeting pollen, honey, and occasionally fruit or dead insects outside of hives.^[46] In honey bee colonies, adults locate hives through olfactory detection of hive odors such as pollen, nectar, and alarm pheromones, flying substantial distances to reach them.^[54] Their small size allows evasion of guard bees, enabling entry through cracks and crevices where they hide to avoid detection and harassment.^[55] Once inside, adults may solicit regurgitated food from worker bees by rubbing their mandibles against the bees' antennae, though they also directly consume available hive resources.^[56] Larval small hive beetles have a diet restricted to hive contents, feeding exclusively on honey, pollen, bee brood, and comb materials during their three instars, which collectively last approximately 6 to 14 days under optimal conditions (28–34°C).^[46] This feeding is facilitated by a mutualistic relationship with the yeast Kodamaea ohmeri, harbored in the larval gut and excreted in feces, which ferments honey and pollen into a nutrient-rich, slimy substrate that enhances larval nutrition and development.^[41] The larvae do not engage in phytophagy within hives, relying instead on processed bee products and brood.^[46] In their native sub-Saharan African range, adult small hive beetles supplement hive feeding with non-host resources such as fallen or decaying fruits like mango, banana, and grapes, though reproduction on these is limited compared to hive diets.^[57] No evidence supports dung consumption as a significant dietary component. Nutritional requirements emphasize high-protein sources; brood consumption supports superior reproductive success and longevity in adults (up to 167 days on honey alone, but enhanced with protein), while larvae achieve higher pupation rates (0.65–0.73) on brood, pollen, or honey-pollen mixtures, underscoring protein's role in beetle fitness.^[58]

Mating and aggregation

The small hive beetle (Aethina tumida) exhibits aggregation behavior that is crucial for mating success, with males typically arriving first at potential sites such as honey bee hives and releasing pheromones to attract conspecifics.^[59] These aggregations form clusters of beetles on hive surfaces or within cracks, where high densities significantly increase mating frequency compared to isolated pairs (p < 0.001).^[59] Female beetles preferentially join these male-initiated groups, suggesting that aggregation serves as a key mechanism for mate location and choice. In invasive ranges, genetic adaptations have led to prolonged aggregation periods in cooler climates, enabling more generations per year (up to 6 in some U.S. populations as of 2025).^[60] Copulation in A. tumida involves multiple matings by both sexes, with females capable of mating with up to eight males and males with at least seven females, indicating low costs associated with repeated copulations.^[61] Each copulatory event lasts approximately 21.5 seconds on average (range: 7.2–67.9 seconds, n=33), during which the male mounts the female from behind.^[59] Females exhibit preferences for males in larger aggregations, potentially selecting for higher-quality mates based on group size or pheromone signals.^[59] Male-male interactions within aggregations include aggressive encounters and attempts at homosexual matings, which increase with age and may serve to establish dominance for access to females.^[59] In contrast, female-female competition is minimal, though females may display aggression toward copulating pairs to disrupt ongoing matings.^[59] Mating activity peaks in warm months, aligning with the species' reproductive seasonality, where up to five generations can occur before breeding ceases in winter.^[62] Infestations and associated aggregations intensify from late summer through fall as adults emerge from pupation.^[46]

Pheromones and chemical signals

The small hive beetle, Aethina tumida, employs pheromones and associated chemical signals to facilitate aggregation, host location, and survival strategies within honey bee colonies. Male beetles produce an aggregation pheromone that attracts both sexes, promoting congregation at suitable sites such as hives or fruit sources. This pheromone consists of a blend of 6-methyl-5-hepten-2-one, nonanal, and decanal in a 2:2:1 ratio, released during feeding on pollen or fruit. When combined with host-derived or fruit volatiles, the blend enhances attraction, enabling beetles to locate resources over distances of several hundred meters to kilometers depending on environmental conditions and wind dispersal.^[63] A key aspect of the beetle's chemical ecology involves its mutualistic relationship with the yeast Kodamaea ohmeri, which the beetles vector into hives. This yeast produces volatile compounds, including isopentyl acetate and related esters, that mimic components of the honey bee alarm pheromone, thereby serving as a kairomone to draw additional A. tumida adults to infested colonies and aiding host location.^[1] Furthermore, K. ohmeri ferments pollen stores, producing nutritional byproducts that support larval development and survival by improving digestibility and providing essential microbial metabolites.^[64]^[29] This symbiosis amplifies infestation risks, as the yeast volatiles reinforce the aggregation signal from the beetle's own pheromone. Adult A. tumida also release defensive secretions in response to threats, primarily from abdominal glands, which contain iridoid compounds and hydrocarbons that deter predators through repellency or toxicity. These secretions function in predator evasion during exposure outside the hive, such as when fleeing bee attacks or soil pupation, by eliciting avoidance behaviors in arthropod predators like ants or spiders. Recent research (as of 2024) has evaluated synthetic aggregation pheromone blends in traps, showing increased capture rates compared to controls and improving early detection in invasive ranges without disrupting bee colonies.^[63] Such tools leverage the beetle's sensitivity to its own pheromones and yeast volatiles for targeted surveillance.^[63]

Parental care and oviposition

Female small hive beetles (Aethina tumida) employ oviposition strategies that prioritize protection from host defenses, laying eggs in concealed locations within honey bee hives such as cracks and crevices in wooden frames, along the bottom board, or directly into capped brood cells.^[14] These sites shield the eggs from removal by foraging bees, enhancing larval survival upon hatching.^[65] Eggs are deposited in clutches, with sizes ranging from 2 to 75 per clutch, though most (61%) contain 6 to 20 eggs, and the average is approximately 16 eggs. Each female produces multiple clutches over her lifespan, totaling 1,000 to 2,000 eggs, distributed across several protected sites within a single hive or across multiple colonies to maximize reproductive output.^[14]^[65] Parental investment is minimal, limited to site selection for oviposition; females provide no provisioning of food or other resources to the eggs or emerging larvae, nor do they exhibit prolonged guarding behavior.^[47] Oviposition activity aligns with host colony availability and environmental conditions, peaking during warmer months when hives are active and humid, such as spring and summer in temperate regions or the rainy season in native sub-Saharan African habitats, allowing for up to five generations annually.^[65] This seasonality ensures eggs develop under optimal temperatures (typically hatching in 3–6 days), synchronizing with abundant food resources in the hive.^[66]

Ecology and interactions

Food resources

The small hive beetle, Aethina tumida, primarily utilizes resources within honey bee colonies, feeding on honey, pollen, and brood as its main nutritional sources across both native sub-Saharan African habitats and invasive regions.^[4] In its native range, these hive stores from African subspecies of Apis mellifera support the beetle's life cycle, with adults and larvae consuming pollen and honey directly while targeting brood for high-protein intake.^[67] This dependence highlights the beetle's role as a facultative parasite, where strong colonies typically limit severe infestations through defensive behaviors.^[4] Beyond hives, A. tumida exploits secondary resources such as wild fruits and vegetables, particularly in its native African ecosystems, where ripe or rotting produce like mangoes, bananas, grapes, strawberries, tomatoes, corn, and melons serves as alternative feeding and oviposition sites.^[68] ^[69] Larvae can develop on these materials, though reproductive output is substantially lower compared to hive resources due to reduced protein content, with field observations showing infrequent natural use and heavy competition from other scavengers like fruit flies (Drosophilidae) and sap beetles (Nitidulidae).^[68] In invasive areas such as North America, Australia, and Europe, the beetle exhibits strong reliance on A. mellifera hives for sustained populations, with alternative plant-based foods playing a minor supplementary role that rarely supports independent reproduction.^[67] ^[68] Nutritional ecology of A. tumida is enhanced by symbiotic yeasts, notably Kodamaea ohmeri, which ferment hive stores and alternative fruits, improving resource palatability and nutritional value to boost larval growth and adult survival rates.^[4] A 2024 study found that beetles fed on bananas developed microbiomes with higher alpha diversity and more carbohydrate-active enzymes compared to hive-fed individuals, potentially facilitating adaptation to non-hive diets during dispersal.^[29] This microbial association contributes to population expansion in resource-rich environments, though in invasive settings, the scarcity of non-hive alternatives constrains overall growth compared to native polydomous habitats.^[70] Habitat proximity to apiaries significantly elevates resource access, as beetles are drawn to hive volatiles while opportunistically utilizing nearby fermenting vegetation, facilitating dispersal and establishment.^[69]

Parasitism of honey bee colonies

The small hive beetle (Aethina tumida) exhibits a parasitic lifestyle by invading honey bee (Apis mellifera) colonies, where adults actively seek out hives through flight, guided by volatile odors from honey, pollen, and brood.^[46] Upon entry, typically into weakened or stressed colonies but also strong ones under high pressure, the beetles conceal themselves in cracks, crevices, or behind hive components to evade detection.^[50] Females commence oviposition within days, depositing clutches of 10–40 eggs in protected sites such as frame gaps, under queen cell cups, or directly into unsealed brood cells, with each female capable of producing over 1,000 eggs during her lifespan.^[71] Eggs hatch in 2–4 days under hive conditions (around 34°C), releasing larvae that burrow into comb and feed voraciously on honey, pollen stores, and bee brood, often tunneling through capped cells to access resources.^[46] To counter host defenses, adult beetles rely on their compact bodies and hardened, sting-resistant elytra, which protect against bee stings and allow them to maneuver rapidly or drop from combs when threatened.^[71] Larvae contribute to evasion by secreting a slimy, fermenting exudate in collaboration with symbiotic yeasts (Kodamaea ohmeri), which contaminates and degrades comb, rendering it unpalatable to bees and facilitating larval mobility while inhibiting effective grooming or removal by workers.^[50] Infestation escalates when adult numbers exceed bee containment capacity, with even modest populations (e.g., dozens per hive) overwhelming weak colonies and prompting absconding or collapse due to resource depletion and structural damage.^[50] Larval outbreaks amplify harm, as feeding destroys up to several frames of comb per generation, leading to hive destabilization; recent spatiotemporal analyses indicate that sustained high larval densities, particularly in shaded apiaries, correlate with severe colony stress, though exact thresholds vary by environmental factors and host vigor.^[72] The beetle shows strong host specificity toward A. mellifera, where it completes its full lifecycle and causes maximal parasitism, but it can opportunistically infest other social bees like bumble bees (Bombus impatiens), resulting in minor brood and store consumption without equivalent hive-wide disruption.^[73]

Host defenses and beetle strategies

Honey bees employ several behavioral and physical defenses to combat small hive beetle (Aethina tumida) infestations within colonies. Guard bees station themselves at hive entrances to detect and repel invading adult beetles, often chasing and confining them to limit access to brood and food stores.^[65] In addition, worker bees use propolis, a resinous substance collected from plants, to construct "prisons" that trap adult beetles, preventing their movement and reproduction; this tactic is particularly effective in African honey bee subspecies, which produce more propolis than European strains.^[74] Bees also seal brood cells breached by beetles with additional propolis or wax to protect developing larvae and remove exposed eggs or young larvae.^[75] In severe infestations, entire colonies may abscond, abandoning the hive to escape overwhelming beetle pressure and thereby denying the pests resources for reproduction.^[14] Small hive beetles counter these defenses through adaptive strategies that exploit hive architecture and bee behaviors. Adult beetles evade detection and stings by rapidly retreating into narrow cracks and crevices within the hive structure, where their small size (approximately 5 mm) and tough elytra provide protection from bee attacks.^[71] Females further enhance offspring survival by inserting eggs into these hidden fissures or directly into capped brood cells using a flexible ovipositor, shielding them from bee removal efforts.^[74] Once inside, adults may adopt a defensive posture or solicit food via trophallaxis, mimicking bee communication to induce workers to regurgitate honey or pollen directly to them.^[75] Beyond evasion, small hive beetles directly harm bees through predation and pathogen transmission. Both larvae and adults feed on bee brood, pollen, and honey, with larvae tunneling through combs and occasionally biting worker bees, contributing to colony stress.^[52] Beetles also serve as vectors for honey bee viruses, such as deformed wing virus, by ingesting infected material from dead bees or brood and mechanically spreading it during feeding or movement within the hive.^[75] Recent studies on co-infestations highlight complex interactions between small hive beetles and Varroa destructor mites. A two-year experiment in the eastern United States found no increased colony morbidity from combined infestations, with higher beetle numbers correlating to reduced mite levels, though both pests independently contribute to winter losses and temperature fluctuations in affected hives.^[76]

Natural enemies

The small hive beetle (Aethina tumida) faces predation from various arthropods and vertebrates in its native sub-Saharan African range. Ants, particularly Pheidole megacephala, act as key predators of beetle larvae, consuming them in soil and near hives in regions like Kenya.^[65] Birds also prey on adult beetles and larvae, contributing to population regulation where African honey bee colonies provide foraging opportunities.^[11] Soil-dwelling insects, including ants, target wandering larvae and pupae during their vulnerable ground phase, where they burrow 5–20 cm deep to pupate.^[11] Parasitic nematodes and entomopathogenic fungi represent significant pathogens affecting A. tumida across life stages. The nematode Heterorhabditis indica (isolate Hi.HRN) demonstrates high virulence, achieving over 80% reduction in adult emergence from soil and up to 43% mortality in emerged adults under semi-field conditions, making it a promising biocontrol agent for soil-dwelling stages.^[77] A 2025 comparative study identified Steinernema carpocapsae (strain All) and Heterorhabditis floridensis (strain K22) as highly virulent against small hive beetle larvae and adults, recommending them for integrated pest management.^[78] Fungal pathogens such as Metarhizium anisopliae (isolate 5680) effectively control larvae and adults, with field trials showing sustained hive protection over 73 days and confirmed infection via hyphal growth in treated beetles.^[79] Other Metarhizium isolates kill more than 70% of larvae within one week, while Beauveria bassiana achieves 99–100% adult mortality in two weeks.^[65] Mites like Caloglyphus hughesi and protozoans in adult Malpighian tubules further act as parasites in laboratory settings.^[65] Competitors for resources include congeneric species such as Aethina concolor, a flower-visiting nitidulid that overlaps in habitat preferences but differs in feeding ecology from the hive-associated A. tumida.^[65] Microbial antagonists, including the aforementioned fungi and nematodes, also compete by infecting and reducing beetle populations.^[65] In its native African range, natural enemies like ants and pathogens maintain A. tumida as a minor pest, but in invasive regions (e.g., North America, Australia, Europe), the absence of these regulators exacerbates outbreaks, highlighting the potential for classical biological control through targeted introductions of African nematodes and fungi.^[65]

Population dynamics

Migration patterns

The small hive beetle (Aethina tumida) exhibits diverse dispersal mechanisms that facilitate both local and long-range movement, enabling range expansion in native and introduced regions. Adult beetles primarily disperse through flight, with studies demonstrating capabilities of covering at least 3.2 km within 24 hours and up to 12 km over a week, though most individuals remain within 50 m of release points, suggesting a preference for short-distance host-seeking.^[30] Flight activity is influenced by environmental factors, including higher temperatures (ranging from 10.7°C to 26.6°C) that enhance recapture rates and wind deviation that directs movement, often toward upwind host colonies.^[30] Additionally, adults may engage in limited phoresy by attaching to honey bees during short-range transport within apiaries, though this is more prominent in human-mediated scenarios than natural dispersal.^[37] Larval dispersal occurs via soil crawling, as mature larvae exit hives and travel distances up to 200 m across the ground surface to locate suitable pupation sites, burrowing 4–8 cm deep into sandy or loamy soils.^[52]^[1] In its native sub-Saharan African range, the small hive beetle achieves gradual natural expansion through contiguous habitats, relying on active flight and wind-assisted dispersal to colonize nearby bee colonies and alternative hosts like fruit or carrion.^[30]^[65] This slow, localized spread is characteristic of its endemic distribution across tropical and subtropical zones, where populations maintain equilibrium with host defenses in strong Apis mellifera scutellata colonies.^[14] Invasive migration, in contrast, is predominantly human-aided, accelerating range expansion beyond natural capabilities. The beetle's introduction to the United States in 1998 occurred via commercial packages of bees imported from Africa to Florida, leading to rapid establishment and spread across southeastern states.^[4] Similarly, in Italy, first detected in Calabria in 2014, the beetle has spread locally between apiaries by 2025 through the movement of infested hives and equipment, remaining confined to southern regions due to containment efforts.^[26] These jumps highlight how trade in beekeeping materials facilitates long-distance invasions, often bypassing ecological barriers.^[74] Recent modeling of spatiotemporal patterns reveals consistent infestation dynamics across ranges, with generalized linear mixed models indicating no significant differences in peak levels between native African sites (e.g., South Africa, Kenya) and invasive areas (e.g., USA, Australia, Italy), though seasonal peaks occur in warmer months.^[72] Location emerges as a key predictor of variation (χ² = 36.4, p < 0.001), underscoring the role of habitat connectivity in dispersal, while lower Italian infestations reflect effective management rather than inherent limitations.^[72]

Seasonal reproduction

The small hive beetle (Aethina tumida) exhibits reproductive patterns closely aligned with climatic conditions in its native sub-Saharan African range, where warm temperatures enable year-round breeding without distinct seasonal interruptions.^[4] In tropical environments, continuous generations occur due to consistently favorable humidity and temperatures above 20°C, supporting ongoing oviposition and larval development throughout the year.^[46] In temperate regions where the beetle has become invasive, such as the southeastern United States and parts of Europe, reproduction is more seasonally constrained, typically producing 2–5 generations annually with peaks during summer months.^[20] Development from egg to adult requires 38–81 days, accelerating at higher temperatures (e.g., 20 days at 35°C versus 54 days at 18.6°C), allowing multiple overlapping cycles when conditions exceed the lower developmental threshold of approximately 10–13.5°C.^[80]^[81] Infestations often surge in late summer to autumn, driven by abundant host resources in active honey bee colonies, with populations declining in winter as adults seek shelter in hives for warmth without reproducing.^[82] The beetle does not enter true diapause but enters a state of quiescence during cold periods below 15–20°C, relying on the insulated microclimate of bee clusters (15–20°C) for survival until spring warming resumes activity.^[83] Reproductive triggers include temperatures above 20°C and the availability of pollen, honey, and brood in host colonies, which stimulate mating and egg-laying shortly after adult emergence.^[46] Fecundity varies markedly with environmental conditions, with females producing up to 1,500 eggs over their lifetime under optimal warm regimes (28–32°C) and resource-rich diets, compared to reduced output in cooler or nutrient-poor settings.^[80] Recent regional studies highlight variations in infestation timing; for instance, spatiotemporal analyses in 2024–2025 indicate earlier summer peaks in warmer southern latitudes versus delayed autumn surges in transitional zones, influenced by local temperature fluctuations and colony strength.^[72]

Genetic variation

A chromosome-level genome assembly of the small hive beetle (Aethina tumida), published in 2023, spans 259 megabase pairs (Mbp) with 99.1% completeness of conserved arthropod genes (BUSCO) and anchoring to eight chromosomes, providing a high-quality reference for genetic studies.^[84] This assembly builds on earlier drafts, such as the 2018 version estimating 234 Mbp across thousands of contigs, and supports detailed analyses of intraspecific variation, including single nucleotide polymorphisms (SNPs) for population tracking.^[85]^[84] Native African populations exhibit higher genetic diversity than invasive ones, with South African and Tanzanian samples showing greater standing variation compared to those in the United States.^[86] Invasive populations in the US display reduced heterozygosity and overall diversity, attributable to founder effects and population bottlenecks during introductions, which originated primarily from South African lineages based on low genetic differentiation (F_ST values of 0.0149–0.1772).^[86] This low diversity suggests a clonal-like propagation in non-native ranges, facilitating rapid spread but limiting adaptive potential without subsequent selection.^[86] Genetic adaptations in A. tumida include expansions in gene families associated with detoxification, such as 116 cytochrome P450 (CYP) genes—exceeding typical insect counts—and 49 glutathione S-transferase (GST) genes, enabling metabolism of insecticides and diverse xenobiotics encountered in invaded habitats.^[85] Chemosensory genes, including odorant-binding proteins and receptors, support pheromone detection and production, with identified aggregation pheromones like 6-methyl-5-hepten-2-one linked to behavioral attraction in both sexes.^[87] Recent transcriptomic studies have highlighted potential resistance mechanisms, including upregulated detoxification pathways under stress, though specific mutations in target-site genes like acetylcholinesterase show limited association with organophosphate or carbamate resistance.^[88] SNPs serve as key markers for tracking A. tumida invasions, with over 4.5 million identified across global populations enabling phylogenetic reconstruction of spread pathways, such as multiple US introductions since 1996 and distinct Asian lineages from African sources like Burkina Faso.^[12] This genetic profiling aids in monitoring adaptive evolution and informing management by distinguishing invasion routes.^[12]

Impact and management

Damage to apiaries

The small hive beetle (Aethina tumida) causes direct and severe damage to honey bee hives in apiaries, primarily through the destructive feeding and tunneling behaviors of its larvae and adults. Larvae, which hatch from eggs laid by female beetles within the hive, rapidly tunnel through comb cells, consuming honey, pollen, and especially bee brood. This activity kills developing bees and destroys the structural integrity of the comb, particularly in newly drawn, delicate wax where damage is most pronounced; older, reinforced combs may withstand moderate infestations better but still suffer losses. The tunneling process releases yeasts carried by the beetles, leading to the fermentation of hive contents into a viscous, slimy mass with a characteristic foul odor resembling rotting oranges, which bees reject and beekeepers cannot salvage.^[89]^[43]^[4] Adult beetles exacerbate hive destruction by feeding directly on honey, pollen stores, and dead or weakened brood, further depleting essential resources and weakening colony vitality. In addition to consumption, adults release feces into honey supers and stored frames, accelerating fermentation and contamination, which renders the honey unpalatable to bees and commercially worthless even if extracted promptly. This feeding not only reduces food availability but also compels bees to expend significant effort in defensive behaviors, such as corralling beetles into hive cracks or "prisons," which diverts workers from foraging and nursing tasks, imposing physiological stress on the colony. In cases of heavy infestation, the cumulative disruption can force entire colonies to abscond, abandoning the hive and leaving apiary operations vulnerable to further losses. Even low numbers of adult beetles can initiate harm in stressed or weakened colonies, though no universally established damage threshold exists.^[89]^[4]^[90] Secondary complications from beetle presence include the potential for disease transmission, as adults and larvae can act as mechanical vectors for bacterial pathogens like Paenibacillus larvae, the causative agent of American foulbrood, by carrying spores on their bodies between infested and healthy hives. While strong colonies may tolerate low beetle numbers, damage thresholds are reached quickly in stressed or weakened apiaries; these effects collectively undermine apiary productivity by compromising hive structure, food quality, and bee health.^[91]^[43]

Economic consequences

The small hive beetle (Aethina tumida) has inflicted substantial economic losses on the beekeeping industry since its introduction to the United States in the late 1990s, with estimates of annual damages reaching up to $3 million by 2004 due to colony destruction and reduced productivity.^[1] In the initial years following its detection in Florida, the beetle led to the loss of at least 20,000 colonies, resulting in direct costs exceeding $3 million.^[92] These figures, drawn from 2000s assessments, underscore the beetle's rapid escalation as a costly invasive pest in non-native regions, where it disrupts commercial beekeeping operations that rely on stable colony numbers for honey production and sales. In Europe, economic pressures from the beetle have intensified, particularly with ongoing outbreaks in southern Italy since 2014, where containment efforts have required compensation payouts totaling 3.2 million euros as of 2025 to support affected beekeepers.^[93] The beetle primarily impacts commercial beekeeping and pollination services, sectors valued at billions globally, by causing substantial reductions in honey yields—sometimes up to complete loss in heavily infested hives—and compromising colony health essential for crop pollination.^[94] Indirect costs further compound these effects, including expenses for colony replacements after destruction of infested hives and implementation of trade restrictions on bee products and equipment to prevent further spread between regions.^[95] Projections for 2025 and beyond indicate escalating economic consequences driven by climate change, which favors the beetle's spread into new areas such as the US West Coast, where suitable conditions in states like Washington could support established populations and amplify losses to pollination-dependent agriculture.^[96] Warmer temperatures are expected to enhance the beetle's invasion potential across Europe and North America, potentially increasing annual global damages through expanded hive infestations and associated industry disruptions.^[97]

Cultural control methods

Cultural control methods for the small hive beetle (Aethina tumida) emphasize preventive practices that maintain hive health and reduce beetle breeding sites without relying on chemical interventions. These strategies focus on apiary sanitation, mechanical barriers, and colony strength to limit adult beetle entry and larval development, forming the foundation of integrated pest management (IPM) programs.^[50] Hive hygiene plays a central role in suppressing beetle populations by eliminating attractive breeding substrates. Beekeepers should conduct regular inspections to remove debris, such as burr comb, dead bees, and pollen stores, which small hive beetles favor for oviposition and larval feeding.^[52] Maintaining a clean apiary environment, including the honey house, prevents beetle buildup; for instance, filled supers and cappings should not be left exposed, and infested equipment must be washed with high-pressure water to remove fermented honey residues that attract beetles.^[43] Stacking or storing infested supers on strong colonies is discouraged, as it facilitates beetle spread and reproduction.^[43] Screened bottom boards are a key hygiene tool, allowing wandering larvae to drop through the hive floor onto a collection tray below, where they desiccate or drown, thereby reducing soil pupation rates.^[52] Mechanical traps provide an effective way to capture adult beetles within and around the hive. In-hive traps, such as commercial designs like the Beetle Blaster, are placed between frames and filled with vegetable oil, soapy water, or diatomaceous earth; these feature entry apertures sized for beetles but too small for bees, leading to beetle entrapment and death by drowning or desiccation.^[98] Oil pan traps positioned under screened bottom boards collect falling adults and larvae, with the viscous oil preventing escape and promoting mortality.^[50] Some traps incorporate attractants like pollen patties or fruit-based lures to enhance capture rates, though oil alone is often sufficient for routine use.^[90] Colony management practices aim to create less favorable conditions for beetle invasion by promoting bee defenses. Keeping colonies strong and populous through timely feeding (avoiding excessive protein supplements that attract beetles) and splitting overcrowded hives reduces susceptibility, as robust bee populations actively harass and remove intruding beetles.^[50] Minimizing propped equipment, such as ensuring tight-fitting lids and frames without gaps, limits beetle hiding spots and entry points.^[98] Selecting queens from hygienic stock that exhibit grooming behaviors can further enhance colony resistance to infestations.^[43] Soil treatments around apiaries target the beetle's pupal stage, which occurs in the ground beneath hives. Placing hives on elevated stands or impermeable surfaces like concrete slabs disrupts larval migration and pupation by exposing soil to sunlight and desiccation.^[1] Tilling the soil periodically or incorporating diatomaceous earth creates a hostile environment for pupae, reducing adult emergence by up to 50% in treated areas.^[1] Sunny, well-ventilated apiary locations further inhibit development, as high temperatures and low humidity deter egg hatching and larval survival.^[52] Integrating these cultural methods into an IPM framework, as updated by the University of Georgia in 2025, prioritizes monitoring beetle thresholds through regular counts and combines hygiene, traps, and site management for sustainable control. This approach minimizes reliance on other interventions while preserving colony productivity.^[43]

Chemical and biological controls

Chemical controls for small hive beetles primarily involve the use of coumaphos strips, marketed as CheckMite+, which are placed inside hives to target adult beetles.^[56] Coumaphos, an organophosphate insecticide, is the only product registered for in-hive treatment in several U.S. states, including Arkansas and Oregon, where it reduces beetle populations by disrupting their nervous systems.^[98]^[71] Permethrin, a pyrethroid, is authorized for use in traps or soil drenches around apiaries and has shown efficacy in controlling adult and larval stages when applied externally.^[99] However, both chemicals pose significant risks to honey bees, including sublethal effects on brood and queens, necessitating careful application and periodic comb replacement to minimize residue buildup.^[41]^[20] Biological controls target soil-dwelling stages of the beetle, where larvae pupate, using entomopathogenic nematodes such as Heterorhabditis bacteriophora. In 2025 laboratory and semi-field tests, Australian isolates of H. bacteriophora demonstrated high virulence, achieving over 80% mortality of wandering larvae and pupae in natural soil at concentrations of 100-500 infective juveniles per gram, with H. indica isolates showing even greater potency (LC₅₀ as low as 26.77 IJs for larvae).^[77] These nematodes are exempt from pesticide registration in multiple countries due to their specificity and safety for non-target organisms, including bees.^[100] Predators like chickens can also suppress larval populations by foraging on them in apiary soils, providing a low-cost, non-chemical option when integrated into farm landscapes. Integrated approaches combine these methods for enhanced suppression, such as pheromone traps baited with the male-produced aggregation pheromone (6-methyl-5-hepten-2-one and related compounds) alongside nematode soil applications to capture adults and disrupt pupation.^[63] In Southern Italy, containment efforts from 2014-2024 utilized in-hive traps like Beetle Blaster® for monitoring and adult capture, paired with soil chemical treatments, achieving containment in Sicily through destruction of affected apiaries in 2014 and 2019 outbreaks (with no detections from 2020 to 2023, though new cases emerged in 2024 requiring renewed efforts) and a 58% decline in cases via surveillance and movement controls.^[93]^[101] Efficacy data indicate that such strategies reduce adult emergence by 59-93% in semi-field conditions when nematodes are applied post-trapping.^[77] Challenges in implementing these controls include emerging resistance to coumaphos and permethrin, first reported in Florida populations in 2019 with up to 10-fold tolerance due to metabolic detoxification mechanisms, prompting rotation of active ingredients to delay further evolution.^[102] Regulatory approvals remain restrictive, as in-hive chemical use requires EPA labeling specific to bees, while biological agents like nematodes face fewer barriers but demand consistent soil moisture for viability; illegal apiary movements have also undermined containment in regions like Italy.^[93]

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Bees and flowers: How to feed an invasive beetle species
May 14, 2019 · The small hive beetle, Aethina tumida, is an invasive parasite species known to infest social bee colonies. Here, we show that solitary bee ...
[68]
The small hive beetle: A potential pest in honey bee colonies in ...
In general, the adults are brown to black in color, oval shaped, and about 5.7 millimeters (approximately 1/4 inch) long or about one-third the size of a honey ...Small Hive Beetle Lookalikes · Life Cycle · Shb In Honey Bee ColoniesMissing: morphology | Show results with:morphology<|control11|><|separator|>
[69]
The biology of the small hive beetle (Aethina tumida, Coleoptera
Small hive beetles, Aethina tumida, are honeybee parasites native to Africa, where they are a minor pest only. In contrast, the beetles can be harmful ...Missing: characteristics | Show results with:characteristics<|separator|>
[70]
(PDF) Potential host shift of the small hive beetle (Aethina tumida) to ...
Aug 5, 2025 · Our findings show that in its new range in North America, bumblebees are potential alternate hosts for the small hive beetle.<|control11|><|separator|>
[71]
[PDF] The Small Hive Beetle - Bayer
From its native geographic range in sub-Saharan Africa, the Small Hive Beetle has spread to every continent except Antarctica during the past 20 years (Figure ...Missing: details | Show results with:details
[72]
[PDF] Small Hive Beetle IPM - Bee Health
Oct 1, 2011 · INTRODUCTION. This booklet provides the beekeeper fundamental and important information about the management of small hive beetles.<|control11|><|separator|>
[73]
Varroa and small hive beetle - Professional Beekeepers
Nov 4, 2024 · Numerous studies have identified both varroa and small hive beetle (SHB) as contributors to colony losses.
[74]
Virulence and biocontrol potential of entomopathogenic nematodes ...
Mar 11, 2025 · The small hive beetle (SHB; Aethina tumida) is a significant pest affecting honey bees and the global beekeeping industry.Missing: suitability | Show results with:suitability
[75]
Efficacy of Entomopathogenic Fungi in Controlling the Small Hive ...
The purpose of this project is to evaluate the fungal pathogen (Metarhizium anisopliae) against the small hive beetle Aethina tumida for the development of a ...<|control11|><|separator|>
[76]
The Effects of Temperature, Diet, and Other Factors on Development ...
Aug 8, 2025 · Temperature affected hatch success, time to hatching, and larval growth. Eggs hatched in 61 h at 21 degrees C but in < 22 h at 35 degrees C.<|control11|><|separator|>
[77]
Temperature-dependent development and survival of small hive ...
We investigated the influence of temperature on the development and survival of immature SHBs. The beetle's immature stages were exposed to different constant ...
[78]
(PDF) Seasonal population dynamics of small hive beetles, Aethina ...
Aug 10, 2025 · Our results also revealed that SHB populations varied throughout the year, with peak infestations observed in the autumn (September and November) ...
[79]
Characterization of Cold Tolerance of Immature Stages of Small ...
May 16, 2021 · Establishment and distribution of invasive insects depends on their cold tolerance especially in temperate regions. The small hive beetle ...
[80]
Genome of the small hive beetle (Aethina tumida, Coleoptera
Dec 7, 2018 · ... Nitidulidae), a worldwide parasite of social bee colonies, provides ... phylogenetic tree of carboxylesterase (COE) genes. The maximum ...
[81]
Comparative genomics suggests local adaptations in the invasive ...
Oct 26, 2021 · Small hive beetles, Aethina tumida, invasive parasites of pollinating bees have recently invaded multiple continents, across a wide range of ...Missing: zones greenhouses
[82]
Identification and Expression Profile of Chemosensory Genes ... - NIH
The small hive beetle is a destructive pest of honeybees, causing severe economic damage to the apiculture industry. Chemosensory genes play key roles in ...
[83]
Characterization of the small hive beetle transcriptome focused on ...
This destructive pest was first discovered in the United States in 1966 and is believed to have spread from South Africa through the Eastern Seaboard (Sheridan ...<|control11|><|separator|>
[84]
Small Hive Beetle - Beekeeping Resources - Bee Program - UGA
The small hive beetle is native to southern Africa where it requires 38-81 days to develop from egg to adult, and five generations per year are possible.
[85]
[PDF] Trapping and Control of the Small Hive Beetle, Aethina tumida, an ...
The larvae are cream-colored and mature on bee brood, honey, and pollen over an average period of 13.3 days inside the honey bee colony and finish maturation in ...
[86]
Small hive beetles, Aethina tumida, are vectors of Paenibacillus larvae
The transmission of honeybee pathogens by free-flying pests, such as small hive beetles (= SHB), would be independent of bees and beekeepers and thereby ...Missing: chalkbrood | Show results with:chalkbrood
[87]
A Survey of Experts' Opinions on the Management of the Small Hive ...
In 2014, when the SHB was first detected in the Italian region of Calabria [20], the EU mandated that Italy set up an SHB surveillance system and implement ...
[88]
[PDF] Ten years of containing small hive beetles in Southern Italy - REABIC
Small hive beetles (Aethina tumida, Coleoptera: Nitidulidae; SHB) are invasive parasites of bee nests that have spread to all habitable continents since 1996,.
[89]
Fight against exotic bee pest heats up as scientists and beekeepers ...
Jan 23, 2017 · ... Small Hive Beetle (SHB) this summer. SHB can reduce honey production in hives right up the east coast of Australia, and the complete loss of ...
[90]
Small hive beetle diagnosis and risk management options
Mar 17, 2015 · Visual inspection of a bee hive or commodity combined with the use of traps is recommended to screen for small hive beetle (SHB) presence.
[91]
September 2024 | WSU Honey Bees + Pollinators Program
Sep 10, 2024 · A WSU Extension factsheet about Small Hive Beetle was released, and the program is seeking input for 2025 workshop ideas.Missing: change models
[92]
Global warming promotes biological invasion of a honey bee pest
Small hive beetles can survive temporarily unsuitable environmental conditions due to the thermoregulatory capacity of honey bee colonies (Schäfer, Ritter, ...
[93]
[PDF] Managing Small Hive Beetles
The adult female beetles will lay egg masses in cracks and crevices around the hive or directly on pollen and brood combs. Beetles may puncture the capping or ...
[94]
Publications at this Location : USDA ARS
Oct 1, 2022 · Coumaphos and permethrin are the only two insecticides currently authorized for use in small hive beetle control.
[95]
https://efsa.onlinelibrary.wiley.com/doi/pdf/10.2903/j.efsa.2015.4048
[96]
First Report on the Mechanisms of Insecticide Resistance in Field ...
Jun 18, 2021 · In addition, the small hive beetle has developed resistance to the pyrethroid and organophosphate insecticides registered for control of ...