Search Results (1,463)

Small scymnine coccinellids, including many Scymnus species, are common aphid predators, but stage-specific feeding data are still limited for many species. We investigated feeding behavior, first-instar prey sharing, stage-specific consumption, and functional responses of Scymnus (Scymnus) folchinii (Canepari) on third-instar Myzus persicae nymphs on chili pepper seedlings. Larvae showed feeding behavior consistent with extra-oral digestion, whereas adults consumed aphids by direct mastication. In the single-prey first-instar assay, prey sharing occurred in all 15 arenas; the period during which two or more larvae fed on the same aphid lasted a median of 31.0 min and accounted for 84.8% of the observed feeding period. Aphid consumption varied with predator stage, exposure time, and initial aphid density. At the highest tested density of 16 aphids, third- and fourth-instar larvae and adults left few aphids alive after 24 h in the seedling micro-arena. Logistic regression diagnosed Type II responses only for adults at 1 h, whereas AIC-based model comparison selected Rogers’ Type II in 15 of 18 stage-by-duration combinations. Short exposures indicated higher attack rates and shorter handling times in fourth instars and adults, whereas longer exposures were affected by prey depletion and satiation. These results show clear stage dependence in aphid consumption by S. folchinii and justify further testing on larger plants and under field conditions. Full article

The tomato leafminer Tuta absoluta (Meyrick) is a devastating invasive pest that threatens tomato production worldwide. Reliance on chemical insecticides raises sustainability concerns, highlighting the need for effective biological alternatives. Combining predators with entomopathogenic nematodes (EPNs) represents a promising strategy, yet their interactions remain poorly characterized. Here, we conducted laboratory bioassays to assess the individual and joint effects of the predatory bug Arma chinensis (Fallou) and four EPN species, Steinernema carpocapsae, S. feltiae, S. riobrave, and Heterorhabditis bacteriophora, against T. absoluta larvae. Under these controlled conditions, H. bacteriophora showed the highest compatibility with A. chinensis, exhibiting the lowest virulence against the predator. Female A. chinensis exhibited strong predation on freely exposed second-instar larvae, but efficiency declined markedly against leaf-mining larvae. Heterorhabditis bacteriophora caused consistently high mortality in second instars regardless of protection. Their combined application resulted in additive mortality with significantly reduced LT₅₀ values. We also observed A. chinensis preying on nematode-infected larvae and occasional infection of the predator under confined conditions. These laboratory findings demonstrate additive effects against T. absoluta, providing preliminary evidence for stage-specific integrated biological control strategies. Full article

To identify novel field control strategies against Pyrrhalta aenescens (Coleoptera: Chrysomelidae) and provide scientific support for its biocontrol in urban tree management, this study investigated the virulence of Beauveria bassiana against this pest under laboratory conditions, as well as its physiological and biochemical effects. Bioassays using the dipping method showed that B. bassiana was pathogenic to all developmental stages of P. aenescens, with the highest virulence observed against early-instar larvae (1st and 2nd instars). For these stages, corrected mortality and mycosis rate were positively correlated with conidial concentration, and the median lethal time (LT₅₀) was the shortest. In contrast, pupae and eggs exhibited the strongest resistance to fungal infection. In leaf-disk choice tests, larvae significantly preferred untreated leaves or those treated with low concentrations of B. bassiana, displaying a concentration-dependent repellent response to the fungus. Physiological measurements revealed that larval body length and weight gain were significantly inhibited following fungal exposure. Further analysis indicated that B. bassiana infection markedly reduced total hemocyte counts and triggered intense melanization and nodulation responses, particularly in younger larvae. Overall, these results suggest that B. bassiana has strong potential for the biological control of P. aenescens. Control measures targeting early-instar larvae are recommended for cost-effective management, providing a scientific basis for developing eco-friendly control technologies based on this entomopathogenic fungus. Full article

Olive, Olea europaea L. (Oleaceae), cultivation is affected by significant yield losses caused by Palpita persimilis Munroe (Lepidoptera: Crambidae), a defoliating pest in South America. Its control currently relies on synthetic pesticides, which have adverse environmental effects. This study investigated native entomopathogenic bacteria isolated from the rhizosphere of olive trees in Tacna, Peru. A total of 36 bacterial isolates were obtained, of which six strains showing more than 70% larval mortality were selected for further evaluation. Morphological and molecular analyses suggested a tentative affiliation of the isolates with bacterial groups related to the genera Lysinibacillus, Paenibacillus, Priestia, and Bacillus. Bioassays demonstrated that larval mortality depended on the bacterial concentration and exposure time. Strains such as Peribacillus sp. UNM achieved 100% larval mortality after 96 h at a concentration of 1 × 10⁹ CFU mL⁻¹. Analysis using a generalized linear model (GLM) with a binomial distribution confirmed that bacterial strain, concentration, and exposure time significantly influenced larval mortality, indicating that mortality responses varied according to bacterial concentration and exposure time. These findings provide preliminary laboratory evidence of entomopathogenic activity associated with native bacterial isolates against P. persimilis and support future investigations aimed at evaluating these isolates under field conditions in olive agroecosystems. Full article

Arthropod natural enemies—encompassing predators and parasitoids—form the backbone of sustainable agriculture, delivering irreplaceable ecosystem services via biological pest suppression. Driven by global demand for eco-friendly alternatives to synthetic pesticides, research in this domain has grown sharply over the past decade. Here, we report a systematic bibliometric analysis of 6515 Web of Science Core Collection papers focused on arthropod natural enemies in biological control (2016–2025), with the goal of charting the field’s intellectual structure. Performance metrics confirmed an initial rapid increase from 2016 to 2019 followed by a plateau and a slight rise in 2025, with the US, China, and Brazil dominating output. Keyword co-occurrence networks pinpointed core themes, including conservation biological control, predatory mites, and integrated pest management (IPM). Temporal trends further revealed a pivot toward applied work on invasive pest systems. Co-citation analysis uncovered six foundational research clusters, while bibliographic coupling of 2021–2025 papers uncovered five active emerging subfields: landscape ecology and habitat manipulation, tri-trophic interaction mechanisms, high-impact invasive pest biocontrol, non-target risk assessment for introduced agents, and fall armyworm integrated management. We synthesize cross-cutting implications and outline future priorities—including AI-enabled rearing systems, functional biodiversity boosting, climate adaptation, and multifunctional landscape tuning. By consolidating historical progress and forward-looking directions, this framework empowers researchers, extension practitioners, and policymakers to scale sustainable pest management worldwide. Full article

The yerba mate psyllid, Gyropsylla spegazziniana, represents a major pest affecting yerba mate production, leading to considerable economic losses. Although several aspects of its ecology and management have been investigated, little is known about the viruses associated with this insect pest. In this study, we conducted the first RNA high-throughput sequencing (HTS) analysis of G. spegazziniana to examine its virome, uncovering a diverse array of previously undescribed RNA viruses. Our analysis led to the identification of five novel viruses spanning different viral lineages. These include representatives with evolutionary affinities to beny-like, picorna-like, and sobemo-like viruses, provisionally designated as Gyropsylla spegazziniana beny-like virus 1 (GSBlV1), Gyropsylla spegazziniana picorna-like virus 1 (GSPlV1), and Gyropsylla spegazziniana sobemo-like virus 1-3 (GSSlV1-3), respectively. Phylogenetic analysis of the bi-segmented, highly divergent sobemo-like viruses revealed that these viruses are grouped with other insect-associated sobemo-like viruses. The beny-like virus clustered together with other insect-associated beny-like viruses, whereas the picorna-like virus clustered together with psyllid-associated picorna-like viruses. Overall, these findings demonstrate that G. spegazziniana harbors a complex and previously uncharacterized virome. This work provides a foundation for further research into the ecological significance, evolutionary patterns, and possible use of these viruses in biological control strategies of this major pest within yerba mate agroecosystems. Full article

The fruit-piercing moth, Eudocima phalonia (Lepidoptera: Erebidae), is a widespread pest in the Pacific region and has recently become economically important again in New Caledonia due to increasingly frequent outbreaks. Improving knowledge of its biology is essential for developing effective monitoring and management strategies. This study aimed to (i) establish a detailed laboratory rearing protocol, (ii) characterize its life cycle and reproductive traits under controlled conditions, and (iii) explore associations between larval coloration, developmental parameters, and seasonal population dynamics. Laboratory colonies were maintained over multiple generations, and field monitoring was conducted across several sites over three years. Larval colour polymorphism was documented, and statistical analyses (ANOVA and linear models) revealed significant associations between larval coloration and pupal morphological traits. However, these results should be interpreted cautiously due to unbalanced sample sizes and the observational nature of the dataset. Differences between sexes in several developmental traits were also observed. Field data showed marked seasonal variation in population abundance. This study provides a detailed rearing protocol and baseline biological data for Eudocima phalonia in New Caledonia, supporting future experimental and applied research. Full article

Bemisia tabaci (whitefly; Hemiptera: Aleyrodidae), a complex of morphologically similar but genetically distinct species, causes enormous agricultural damage worldwide. Farmers incur billions of dollars in losses each year from whiteflies, both through direct feeding damage and from the transmission of numerous plant viruses. Important crops that are heavily damaged by whiteflies include tomato, eggplant, cucumber, cotton, cucurbits, beans, and cassava. The global invasiveness and persistence of B. tabaci are largely attributed to its exceptional biological traits. Understanding these traits is essential for developing effective, long-term pest management strategies. This review describes in detail how the basic biology studies of B. tabaci provide a foundation for developing pest management strategies. Specifically, we discuss: (1) insights into the development of insecticide resistance can guide resistance management strategies; (2) knowledge of natural enemies supports the advancement of biological control approaches; and (3) understanding plant–insect interactions reveals molecular targets for innovative pest management solutions. We also examine emerging research trends and offer future perspectives on how ongoing studies may drive the development of next-generation control strategies (RNA interference, clustered regularly interspaced short palindromic repeats—CRISPR-associated protein 9 (CRISPR-Cas9), and horizontally transferred genes as targets). Full article

In this study, we present a discrete switching host–parasitoid model that incorporates biological and chemical control interventions within the integrated pest management (IPM) measures. The coupling of multi-tactic control measures induces rich and complex dynamical behaviors in the proposed system. We begin by systematically characterizing the existence and stability of fixed points in the control subsystem. The analysis then proceeds to demonstrate how the system undergoes multiple bifurcation routes, including period-doubling, transcritical, and Neimark–Sacker bifurcations. Building on this theoretical foundation, extensive numerical simulations are conducted, not only corroborating our analytical predictions but also revealing emergent phenomena such as cascading period-doubling routes and chaotic regimes. Finally, high-resolution two-parameter stability diagrams are employed to identify the critical dynamical transition boundaries, and the corresponding ecological implications for practical pest management decision-making are elaborated in depth. Full article

The whitefly Bemisia tabaci is a major pest of greenhouse-grown tomato, causing significant yield and quality losses worldwide. This study evaluated the population dynamics of B. tabaci on tomato crops maintained at a maximum temperature of 24 ± 1 °C and assessed the effectiveness of two generalist predators, Nesidiocoris tenuis and Orius laevigatus, applied individually or in combination under greenhouse conditions in Saudi Arabia. Whitefly populations increased progressively throughout the study, reaching peak densities of 32.24 eggs and 124.00 ± 7.78 nymphs per leaf. Predator release significantly reduced B. tabaci populations at both the egg and nymphal stages. N. tenuis showed greater efficacy against eggs, achieving a 67.44% reduction, whereas O. laevigatus was slightly more effective against nymphs, with a 63.30% reduction. Notably, the combined release of both predators resulted in the greatest suppression of whitefly populations, reducing egg and nymphal densities by 79.50% and 78.02%, respectively, suggesting additive or synergistic interactions between the two predators. The dual-predator treatment also significantly improved yield-related parameters, including fruit number, fruit size, and total yield per plant, without adversely affecting fruit quality. In addition, vitamin C content increased under the combined predator treatment. These findings demonstrate that the integration of N. tenuis and O. laevigatus enhances biological control efficacy and supports sustainable integrated pest management strategies for greenhouse tomato production. Full article

This study presents the findings of on-farm trials conducted in Hungary between 2023 and 2025, evaluating the efficacy of inundative Trichogramma releases against the European corn borer (ECB) and the cotton bollworm (CBW). The research assessed three Trichogramma preparations, including solo T. brassicae (TB) and two species mixtures: (1) T. dendrolimi, T. cacoeciae, and T. brassicae (TSM1) and (2) T. brassicae and T. pintoi (TSM2). The timing of the releases was synchronized with pest swarming and maize phenology. The efficacy of Trichogramma-based biological control was assessed by comparing the number of damaged plants and the number of pest larvae detected in treated and untreated plots. Statistical analyses revealed a significant association between the release of parasitoids and a reduction in pest damage. The efficacy of the Trichogramma releases was determined using Abbott’s formula. In our research, the following pattern emerged: (1) medium efficacy (ranging from 40% to 68.2%) occurred under low pest pressure and optimal weather conditions; (2) low efficacy (35.5% and 33.3%) occurred under medium pest pressure and suboptimal climatic conditions; and (3) no efficacy occurred under high pest abundance combined with unfavorable weather. Our findings suggest that Trichogramma-based products can serve as complementary components of Integrated Pest Management (IPM); however, they also emphasize that parasitism by Trichogramma wasps is influenced by several factors, such as climatic conditions and pest abundance, indicating that additional plant protection treatments may be necessary, for example, under high pest pressure and/or suboptimal climatic conditions. Full article

Cydia pomonella (Linnaeus, 1758) is considered one of the major pests affecting global pome fruit production due to its wide distribution, cryptic feeding habit, high economic impact, and continuous evolution of insecticide resistance. Historically, management of this species has relied on repeated pesticide applications, which have been associated with environmental impacts, occupational exposure, pesticide residues in food, and compromised sustainability of pesticide-dependent agricultural systems, reinforcing the relevance of integrated One Health approaches. This narrative review analyzed global management strategies for C. pomonella published between 2014 and 2024 and indexed in the Scopus, Web of Science, and SciELO databases. The reviewed studies demonstrate a gradual transition from predominantly chemical-based programs toward integrated strategies involving pheromone-based monitoring, mating disruption, biological control, and preventive plant biosecurity measures. Behavioral and biological approaches showed potential to reduce dependence on recurrent insecticide applications, particularly when associated with phytosanitary surveillance and integrated pest management programs. However, the effectiveness of these approaches remains influenced by insecticide resistance, climatic variability, and local ecological conditions. The evidence also suggests that the impacts of C. pomonella management are not limited to phytosanitary protection, involving interactions related to environmental sustainability, food safety, and human exposure to pesticides. Despite the relevance of the One Health approach, its operational incorporation into agricultural pest management remains limited, especially regarding the integration of research conducted under the One Health perspective. In this context, the sustainable management of Cydia pomonella requires integrated strategies capable of connecting phytosanitary surveillance, preventive plant biosecurity, and agricultural and ecological sustainability in order to ensure food security and population health. Full article

Alphitobius diaperinus (Panzer) (Coleoptera: Tenebrionidae) is a common pest in poultry farms, causing significant economic damage, spreading easily and quickly. The species is resilient, adaptable, and capable of thriving in a variety of environments, and both larvae and adults can hide in hard-to-reach places; thus, control becomes highly challenging. Moreover, the species has developed resistance to commonly used insecticides, increasing the need to adopt integrated pest management strategies. Hence, this study examined the mortality dynamics of A. diaperinus larvae exposed to the entomopathogenic nematodes (EPNs) Heterorhabditis downesi Stock, Griffin & Burnell 2002 (Rhabditida: Heterorhabditidae) and Steinernema kraussei (Steiner, 1923) (Rhabditida: Steinernematidae) across a range of temperatures, dose rates, and exposure intervals. The patterns of larval mortality closely followed the classical EPN infection timeline: limited mortality during the first hours, a pronounced increase between day 2 and 4, and high cumulative mortality after day 8. Steinernema kraussei produced moderate early mortality, increasing by day 8, across all tested temperatures, reflecting its relatively slower but effective infection progression. In contrast, H. downesi induced higher early mortality at moderate temperatures and stronger dose-dependent responses. Temperature significantly modulated infection in both species, with reduced performance at 35 °C, particularly for H. downesi, although high-dose treatments achieved substantial mortality. The significant temperature × dose × time interactions align with established EPN biology and previous research on both species and, overall, the results confirm that they both possess strong pathogenic potential against A. diaperinus, while their performance characteristics support their suitability as biological control agents for poultry facilities. Full article

The crop system of soybean–maize succession has been adopted widely in the Neotropics. It inadvertently provides continuous food resources (green bridges) to stink bugs (Hemiptera: Pentatomidae), favoring outbreaks. Thus, stink bugs need to be managed within a broader and more holistic perspective. Not just individual fields but the whole landscape should be monitored and managed, since these pest outbreaks are deeply influenced by neighboring fields and successive crops in the same field. During the first crop season, stink bugs should be controlled only in the reproductive stage of soybean (from the R3 to R6 plant development stage), when the population is equal to or higher than the economic threshold (ET) of two stink bugs·m⁻¹. Biological control or plant resistance strategies should be used instead of chemicals whenever possible. When the ET is reached at R7 or R8, more tolerant maize varieties (fast growing) should be sown in the second crop season with the seed treatment using recommended insecticides. Grain losses during harvest and the presence of weeds must be avoided at the end of the soybean season. Chemical insecticide sprayings on maize might still be necessary if Diceraeus spp. outbreaks equal or surpass three stink bugs·m⁻¹ during early maize stages (until V7). This more precise and less impactful management of the agroecosystem will promote a more sustainable and resilient management of these polyphagous pests. Full article

Wild maize (teosinte) has been reported to be less susceptible to biotic and abiotic stresses than its modern relative, corn. The composition of the teosinte root microbiome may be linked to traits such as drought tolerance and pest resistance. Trichoderma spp. are ubiquitous saprotrophic fungi found in the plant rhizosphere, enhancing host plant growth and crop productivity while alleviating biotic and abiotic stresses. The present study identified ten Trichoderma fungal isolates associated with the rhizosphere microbiome of teosinte (Zea mays spp. mexicana) and performed in vitro screening to assess both their multi-trait plant growth-promoting activities and their biological control potential against the phytopathogens Aspergillus flavus and Fusarium verticillioides. Additionally, interaction tests were conducted to evaluate the phytostimulant effect of Trichoderma spp. on maize (Zea mays) seed germination. Taxonomic and phylogenetic analysis identified five different Trichoderma species: T. rifaii (TA and TH); T. azevedoi (TB and TI); T. afroharzianum (TE); T. hamatum (TF and TG); and Trichoderma sp. (aff. bannaense) (TC, TD, and TJ). Partial least squares discriminant analysis revealed the isolates TF, TG, and TJ to have the highest potential for use as biocontrol and biostimulant agents. The present study is the first to examine Trichoderma species associated with the teosinte microbiome, and the results suggest that Trichoderma isolates are a potential sustainable alternative for improving maize cultivation. Full article