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Predation efficiency of the green lacewings Chrysoperla agilis and C. mutata against aphids and mealybugs in sweet pepper

Published online by Cambridge University Press:  09 September 2022

Galini Koutsoula ,
Athanasia Stamkopoulou ,
Apostolos Pekas ,
Felix Wäckers ,
George Broufas  and
Maria L. Pappas Open the ORCID record for Maria L. Pappas [Opens in a new window]
Galini Koutsoula
Affiliation:
Department of Agricultural Development, Faculty of Agricultural and Forestry Sciences, Democritus University of Thrace, Pantazidou 193, 68200 Orestiada, Greece
Athanasia Stamkopoulou
Affiliation:
Department of Agricultural Development, Faculty of Agricultural and Forestry Sciences, Democritus University of Thrace, Pantazidou 193, 68200 Orestiada, Greece
Apostolos Pekas
Affiliation:
Biobest Group N.V., Ilse Velden 18, Westerlo 2260, Belgium Instituto Agroforestal Mediterráneo, Universidad Politécnica de Valencia, Camino de Vera, s/n 46022 Valencia, Spain
Felix Wäckers
Affiliation:
Biobest Group N.V., Ilse Velden 18, Westerlo 2260, Belgium Lancaster Environment Centre, Lancaster University, Lancaster, UK
George Broufas
Affiliation:
Department of Agricultural Development, Faculty of Agricultural and Forestry Sciences, Democritus University of Thrace, Pantazidou 193, 68200 Orestiada, Greece
Maria L. Pappas*
Affiliation:
Department of Agricultural Development, Faculty of Agricultural and Forestry Sciences, Democritus University of Thrace, Pantazidou 193, 68200 Orestiada, Greece
*
Author for correspondence: Maria L. Pappas, Email: [email protected]
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Abstract

Chrysoperla species include well-known predators of aphids and other soft-bodied arthropods. As such, they are considered important biological control agents of herbivorous pests in agroecosystems where many of green lacewings species occur. Despite the high number of species of the genus Chrysoperla, only a few have been assessed for the predation efficiency of their larvae against pests infesting plants, and even fewer are currently marketed for use in biocontrol practice. Difficulties in species identification within the Chrysoperla carnea complex species in particular has been related to varying success of commercial C. carnea s.l. releases in the field. In this study, we assessed the ability of two Chrysoperla species, Chrysoperla agilis a member of the carnea cryptic species group, and Chrysoperla mutata of the pudica group to consume aphid and mealybug individuals and suppress their populations in sweet pepper plants. We found that third-instar larvae of both species were able to consume a high number of aphids (approximately 120 nymphs per larva) and mealybugs (approximately 105 nymphs per larva) within 24 h. Furthermore, the release of second-instar larvae of both C. agilis and C. mutata was shown to be remarkably efficient in suppressing the pest populations in long-term greenhouse experiments. Aphid populations were suppressed by approximately 98% and mealybugs by 78% as compared to control plants. Our results highlight the predation efficiency and the biocontrol potential of two widespread Chrysoperla species for their use in pest control.

Keywords

AphidsbiocontrolChrysoperla spChrysopidaemealybugspepper
Type
Research Paper
Information
Bulletin of Entomological Research , Volume 113 , Issue 2 , April 2023 , pp. 162 - 168
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Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

The family Chrysopidae includes approximately 1200 species. The larvae of all species are voracious predators and feed on key pests of crops such as aphids, mealybugs, lepidopteran and coleopteran eggs, thrips and spider mites (Canard et al., Reference Canard, Séméria and New1984; McEwen et al., Reference McEwen, New and Whittington2001). In addition, chrysopids of certain genera (e.g. Chrysopa) are voracious during the adult stage as well (Brooks and Barnard, Reference Brooks and Barnard1990). Chrysopids are widespread in several habitats including agroecosystems and forests (McEwen et al., Reference McEwen, New and Whittington2001). Particularly, because of the occurrence of several species in agricultural systems and due to the voracity of certain species, green lacewings of the family Chrysopidae are considered important biological control agents of key pests (Tauber et al., Reference Tauber, Tauber, Daane and Hagen2000; Pappas et al., Reference Pappas, Broufas and Koveos2011). Despite the fact that many chrysopids are well known for their high predation efficiency against several pests, only a few species are currently commercially available, with Chrysoperla carnea sensu lato being the most widely used in biological control (Pappas et al., Reference Pappas, Broufas and Koveos2011). Concretely, among the 20 described species of the genus Chrysoperla, ‘Chrysoperla carnea’ is the only species marketed by the European biocontrol industry for aphid control. Yet, a number of other Chrysoperla species may prove more efficient/suitable than the commercial C. carnea in controlling different pests under specific conditions.

Our previous work on the European species of the C. carnea complex has revealed their potential as biological control agents for use in central and southern Europe (Pappas et al., Reference Pappas, Karagiorgou, Papaioannou, Koveos and Broufas2013; Athanasiadis et al., Reference Athanasiadis, Pappas and Broufas2021). These lacewings are reproductively isolated species that can be distinguished by the low-frequency species-unique courtship songs they produce by vibrating their abdomen on the substrate before mating (Brooks, Reference Brooks1994; Henry et al., Reference Henry, Brooks, Thierry, Duelli, Johnson, McEwen, New and Whittington2001; Noh and Henry, Reference Noh and Henry2010; Henry et al., Reference Henry, Brooks, Duelli, Johnson, Wells and Mochizuki2013). Among the five European species of the C. carnea group, Chrysoperla agilis has been recorded in southern Europe, southwestern Asia to northern Iran and central Alaska (Henry et al., Reference Henry, Brooks, Duelli and Johnson2003; Henry et al., Reference Henry, Brooks, Johnson, Wells and Duelli2011). C. agilis is able to survive and reproduce in a wide range of temperature regimes and larvae prey upon factitious foods such as Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) eggs in the lab (Pappas et al., Reference Pappas, Karagiorgou, Papaioannou, Koveos and Broufas2013; Athanasiadis et al., Reference Athanasiadis, Pappas and Broufas2021). These findings, along with its wide distribution and habitat range and occurrence in agricultural crops (Henry et al., Reference Henry, Brooks, Duelli and Johnson2003; Henry et al., Reference Henry, Brooks, Johnson, Wells and Duelli2011), render C. agilis a promising candidate for mass-rearing and use in augmentative biological control.

Chrysoperla mutata (McLachlan) is not a member of the carnea complex but of the pudica group (Brooks, Reference Brooks1994; Duelli, Reference Duelli, McEwen, New and Whittington2001). With a distribution ranging from Africa to the Mediterranean Europe and Asia, and lately in Russia and Tenerife (Thierry et al., Reference Thierry, Canard and Mirmoayedi2004; Canard and Thierry, Reference Canard and Thierry2013; Duelli et al., Reference Duelli, Monserrat and Henry2019; Makarkin and Shchurov, Reference Makarkin and Shchurov2019) it is considered to be able to survive and reproduce in areas with dry and hot summers as well as mild winters (Szentkirályi, Reference Szentkirályi, McEwen, New and Whittington2001). As with the carnea cryptic species, the biology and ecology of C. mutata as well as its predation efficiency against crop pests remain largely unexplored (Canard and Thierry, Reference Canard and Thierry2013).

The two lacewings show overlapping distribution in southern Europe, and in addition, C. agilis can be found in northern habitats as well. Moreover, our experience suggests that the rearing of C. mutata in large numbers is feasible due to its low occurrence of cannibalism as well as the wide prey/food range. Given the need to increase biocontrol solutions against key pests of crops and the potential of both C. agilis and C. mutata for use in augmentative biocontrol, we here evaluated the predation efficiency and ability of both species to suppress the populations of the green peach aphid Myzus persicae and the cotton mealybug Phenacoccus solenopsis on sweet pepper plants. Both pest species cause serious damage to many crops including greenhouse sweet pepper (van der Ent et al., Reference van der Ent, Knapp, Klapwijk, Moerman, van Schelt, de Weert, Girard and Stroobach2017; Pekas et al., Reference Pekas, De Craecker, Boonen, Wäckers and Moerkens2020; Bragard et al., Reference Bragard, Di Serio, Gonthier, Jaques Miret, Justesen, Magnusson, Milonas, Navas-Cortes, Parnell, Potting, Reignault, Thulke, Van der Werf, Civera, Yuen, Zappalà, Gregoire, Malumphy, Campese, Czwienczek, Kertesz, Maiorano and MacLeod2021). The results will be useful to assess the use of C. agilis and C. mutata in applied biocontrol programmes.

Materials and methods

Laboratory rearing of green lacewings

The laboratory colonies of C. agilis and C. mutata were maintained at 25 + 1°C and 16:8 LD. The colony of C. mutata was established with adults collected in the area of Chalkidiki (Northern Greece), whereas C. agilis was collected in Crete (Southern Greece). The larvae of both species were fed on frozen E. kuehniella eggs and adults were maintained in cylindrical plastic cages (35 cm in height × Ø25 cm), as described by Pappas et al. (Reference Pappas, Broufas and Koveos2007). Briefly, adults were reared in groups of females and males in cages and fed with a protein-based liquid food (a volumetric mixture of honey, sugar, yeast hydrolysate and water, 1:1:1:1) applied daily on the top of the mesh covering each cage. Lacewing identification was performed by song analysis and morphological traits by Prof. Charles S. Henry (University of Connecticut).

Experimental green lacewing larvae

For the experiments, different instars of lacewing larvae were used. For this purpose, eggs were collected at 24 h intervals from the lacewing colonies and maintained individually in Petri dishes until hatching. Afterwards, the larvae were reared until the desired instar (second or third, depending on the experiment, see below) with ad libitum access to E. kuehniella eggs.

Herbivores used as prey in the experiments

Two different prey species were tested in the experiments: (a) the aphid M. persicae that originated from tobacco in the area of Komotini (Northern Greece) and the mealybug P. solenopsis that was collected from sweet pepper plants in the area of Crete. Both species were reared on potted sweet pepper (Capsicum annuum L.) plants under laboratory conditions (25 ± 2°C, 65 ± 5% RH, 16:8 LD).

Plants used in the experiments

Pepper (C. annuum L., cv P13) seedlings were transplanted in plastic pots (0.5 litres) filled with peat (Klasmann-Deilmann GmbH). Plants were maintained in a growth chamber (25 ± 2°C, 65 ± 5% RH and 16:8 LD) and were watered and fertilized once per week (N-P-K, 10-10-10, 1 g l−1). For the experiments, we used plants 4-weeks after transplantation (d28).

Predation efficiency against aphids and mealybugs

Prey consumption by C. agilis and C. mutata when provided aphids or mealybugs was assessed in the laboratory and the greenhouse.

Laboratory trials

In the laboratory, daily prey consumption by third-instar larvae of C. agilis and C. mutata was assessed in Petri dish assays at 25 ± 1°C, 16:8 LD. The larvae were placed individually in Petri dishes (Ø5 cm) without food for 24 h. Afterwards, each lacewing larva was offered 200 (third–fourth instar) aphid (M. persicae) nymphs or 150 newly hatched mealybug (P. solenopsis) nymphs. Prey consumption was recorded after 24 h. Each treatment included 15 replicates (lacewing larvae).

Greenhouse experiments

In the greenhouse, 60 potted pepper plants were infested with either 100 aphid (third–fourth instar) nymphs or one mealybug female carrying an egg-sac (d28). The plants were placed individually in insect-proof cages (60 × 33 × 33 cm3) (25 ± 1°C, 16:8 LD). Forty plants were assigned to the predator treatment (i.e. 20 repetitions per predator). For this, ten lacewing larvae from each lacewing species (second instar) were transferred onto each plant, both 3 days after the aphid infestation (d31) and again 1 week later (i.e. 20 lacewing larvae were released per plant in total). Lacewing larvae had been fed with E. kuehniella eggs until they reached the second larval instar. Another 20 plants were infested with aphids without predators being released (control treatment). Aphid numbers per plant were assessed 1 week after the second release (d42) both in the predator and control plants (fig. 1a).

Figure 1. Experimental set-up used to evaluate the predation efficiency of larvae of C. mutata and C. agilis on pepper plants in insect cages infested by (i) M. persicae or (ii) P. solenopsis. Pest suppression was assessed 11 or 21 days after lacewing (second-instar larvae) initial release on the plants for aphids and mealybugs, respectively.

For the mealybug experiments, 60 plants were infested with one mealybug female carrying an egg-sac (d0). Forty plants were assigned to the predator treatment, where 15 lacewing larvae (second instar) of each lacewing species were transferred on each plant after 1 (d35), 2 (d42) and 3 weeks (d49) (i.e. 45 lacewing larvae per plant in total). Lacewing larvae had been fed with E. kuehniella eggs until the second larval instar. Another 20 plants were infested with mealybug without predators being released (control treatment). Mealybug numbers per plant were assessed 1 week after the last predator release (d56), both in the predator and control plants (fig. 1b).

Lacewing individuals (i.e. emerging adults and live lacewing pupae) inside each cage were also recorded per plant (insect cage).

Data analysis

To compare daily prey consumption between the different lacewing species a t-test was used. In the greenhouse experiment, failing to meet the requirements for parametric analysis, means were compared with the non-parametric Kruskal–Wallis test, followed by pairwise comparisons with Dunn's test. Statistics were performed using SPSS (2020).

Results

Short-term prey consumption

Prey consumption by third-instar lacewing larva in 24 h was 104.3 ± 4.4 and 103.5 ± 3.6 mealybug individuals for C. agilis and C. mutata, respectively, and 116.0 ± 4.9 and 118.2 ± 4.9 aphid individuals for C. agilis and C. mutata, respectively (fig. 2). No significant differences were recorded in the mean numbers of mealybugs (t = 0.153; df = 28; P = 0.88; fig. 2a) or aphids (F = 0.316; df = 28; P = 0.754; fig. 2b) consumed by C. agilis and C. mutata.

Figure 2. Mean number of (a) mealybugs and (b) aphids consumed by C. mutata (CM) and C. agilis (CA) third-instar lacewing larvae in 24 h in laboratory Petri dish assays (25 ± 1°C, 16:8 LD). ns: P > 0.05.

Pest suppression in the greenhouse

Aphid population levels were significantly affected by the release of the lacewing larvae (χ2 = 49.64; df = 2; P < 0.001). Mean number of aphids per plant was 4146.2 ± 151.3 individuals in control plants and decreased to 48.9 ± 5.5 and 11.4 ± 2.3 aphids after releasing C. mutata and C. agilis larvae, respectively (fig. 3a). Out of the initial number of released lacewings (20 larvae in total per plant), a low number of lacewing individuals per species (3.0 ± 1.3 and 2.6 ± 1.2 pupae per cage for C. mutata and C. agilis, respectively) was recorded in each cage for both species (U = 162.0; Z = −1.067; P = 0.286; fig. 3b).

Figure 3. Mean number of (a) aphids 14 days (d42) after plant infestation with 100 aphid (third–fourth instar) nymphs followed by the release of C. mutata (CM) or C. agilis (CA) second-instar larvae (ten larvae were released per species twice on each plant at d31 and d35, i.e. 20 larvae in total) as compared to control (CON) plants (no lacewing release), and (b) live individuals (i.e. emerging lacewing adults and live pupae) per lacewing species in each cage, Kruskal–Wallis multiple comparison analysis with a Dunn's post-hoc test. ns,  not significant, *P < 0.05, **P < 0.01, ***P < 0.001.

The level of mealybug infestation was significantly affected by the release of the lacewing larvae as well (χ2 = 39.403; df = 2; P < 0.001). The mean number of mealybugs per plant was 808.4 ± 55.3 individuals in control plants, which decreased to 208.5 ± 26.7 and 201.2 ± 25.5 mealybugs after releasing C. mutata and C. agilis larvae, respectively (fig. 4a). Out of the initial number of released lacewings (45 larvae in total per plant), the number of emerging lacewing adults and live pupae was 7.8 ± 0.7 and 3.2 ± 0.3 for C. mutata and C. agilis respectively (U = 29.5; Z = −4.655; P < 0.001; fig. 4b).

Figure 4. Mean number of (a) mealybugs 28 days (d56) after plant infestation with one mealybug female carrying an egg-sac followed by the release of C. mutata (CM) or C. agilis (CA) second-instar larvae (per species, 15 larvae released thrice on each plant at d35, d42 and d49, i.e. 45 larvae in total) as compared to control (Con) plants (no lacewing release), and (b) live individuals (i.e. emerging lacewing adults and live pupae) per lacewing species in each cage, Kruskal–Wallis multiple comparison analysis with a Dunn's post-hoc test. ns, not significant, *P < 0.05, **P < 0.01, ***P < 0.001.

Discussion

In the present study, we assessed the ability of two green lacewing species of the genus Chrysoperla to consume individuals of two key pests of vegetable crops, the green peach aphid M. persicae and the mealybug P. solenopsis. Furthermore, we compared the two lacewings for their efficacy in suppressing the populations of these two pests when infesting pepper plants in the greenhouse. We found that both lacewings can similarly consume individuals of the green peach aphid as well as mealybugs. In addition, both were shown to be efficient in suppressing aphid and mealybug populations in the greenhouse, relative to a predator-free control.

Short-term consumption of aphids and mealybugs was similar between the two lacewing species. Both C. agilis and C. mutata third-instar larvae were shown to be able to consume a relatively high number of aphids (approximately 120 nymphs per larva) within 24 h. These results confirm the high voracity of both lacewing species and confirm what is already known about the predation efficiency of late instar larvae of Chrysoperla species (Canard and Principi, Reference Canard, Principi, Canard, Semeria and New1984; Pappas et al., Reference Pappas, Broufas and Koveos2011). Notably, both lacewings were also capable of consuming a high number of mealybug individuals, which can be an additional asset of these chrysopid species, which are largely seen as aphidophagous predators. Other Chrysoperla species have previously been recorded as natural enemies of different mealybug species in agroecosystems (McEwen et al., Reference McEwen, New and Whittington2001). However, the suitability of mealybugs to support the development and survival of lacewings should be further explored. For example, the citrus mealybug Planococcus citri was found to be suboptimal as prey for Chrysoperla lucasina, another European species of the carnea group (Messelink et al., Reference Messelink, Vijverberg, Leman and Janssen2016). Similarly, different aphid species may differentially affect the life-history traits of chrysopids, as was shown for example in the case of Pseudomallada prasinus and Chrysoperla sinica (Pappas et al., Reference Pappas, Broufas and Koveos2007; Khuhro et al., Reference Khuhro, Chen, Zhang, Zhang and Wang2012).

On the other hand, the (long-term) pest suppression in the greenhouse was found to be remarkably efficient for both lacewing species. Aphid populations were suppressed, with C. agilis being slightly more efficient than C. mutata with approximately 10 vs. 50 aphids found alive per plant, respectively as compared to the control (approximately 4000 aphids per plant). With regard to the suppression of mealybug populations in the greenhouse, both C. agilis and C. mutata larvae resulted in a reduced mealybug population growth, relative to the predator-free control, with no significant differences between the two lacewings. Hence, our results highlight the potential of both lacewing species as aphid and mealybug predators. At this point, it is important to consider that pepper plants used in our experiments were infested with a quite high number of pest individuals (100 third–fourth-instar aphid nymphs or one mealybug female carrying an egg-sac) suggesting that an earlier release at lower pest infestations could have resulted in a more pronounced reduction or even the complete pest elimination. Furthermore, it is also important to acknowledge that the releases of the predators took place in cages that may have facilitated the encounters and eventually consumption of the prey. More experiments under more realistic field conditions are needed to better evaluate the potential of C. agilis and C. mutata to control aphids and mealybugs in sweet pepper.

The reduction in aphid populations achieved by C. agilis larvae was more pronounced when compared to C. mutata. This can be explained by species-specific differences in the predation potential of each instar or the developmental rates of the two lacewings. While no studies have assessed the life-history traits of C. mutata so far, second-instar larvae of C. agilis require approximately 11 days to complete development when fed with E. kuehniella eggs at 27°C (Pappas et al., Reference Pappas, Karagiorgou, Papaioannou, Koveos and Broufas2013) suggesting that most of the released larvae (20 larvae per plant) may have pupated by the recording day. On the other hand, in the case of the mealybugs experiment that ended 2 weeks later, possibly most of the larvae released in the first two time points (in total 30 larvae per plant in d35 and d42) of both C. agilis and C. mutata may have pupated/reached adulthood. Nevertheless, a significantly higher number of C. mutata as compared to C. agilis individuals was recorded on mealybug-infested plants (approx. eight vs. three individuals) 3 weeks after the initial release of second-instar larvae, whereas this difference was not seen 11 days after the release of second-instar larvae on aphid-infested plants. Further experiments are required to verify these differences and assess the population growth of the two lacewings on plants infested by each pest.

Despite the wide distribution of C. agilis and C. mutata, relatively little is known about their feeding habits, life-history traits and ability to suppress pest populations. Both species show a preference for Mediterranean climates (Szentkirályi, Reference Szentkirályi, McEwen, New and Whittington2001; Henry et al., Reference Henry, Brooks, Duelli and Johnson2003) and under these conditions are capable of consuming aphid and mealybug individuals and suppressing their populations. Hence, both species can be promising biological control agents in warmer and dry parts of their distribution range, where other species of the -carnea group are not common (Tauber et al., Reference Tauber, Tauber, Daane and Hagen2000; Henry et al., Reference Henry, Brooks, Duelli and Johnson2003; Canard and Thierry, Reference Canard and Thierry2013; Pappas et al., Reference Pappas, Karagiorgou, Papaioannou, Koveos and Broufas2013; Duelli et al., Reference Duelli, Monserrat and Henry2019; Athanasiadis et al., Reference Athanasiadis, Pappas and Broufas2021). With regard to their feeding habits, C. agilis was previously shown to prey on E. kuehniella eggs (Pappas et al., Reference Pappas, Karagiorgou, Papaioannou, Koveos and Broufas2013), whereas there is only limited information on C. mutata larval ability to consume aphids such as Lipaphis erysimi and the spider mite Tetranychus turkestani (Zhang, Reference Zhang2003; Abdulhay, Reference Abdulhay2021). Furthermore, we show in the present study that C. mutata can be reared on E. kuehniella eggs, while preying on M. persicae and P. solenopsis nymphs.

Previous studies suggest that C. agilis and C. mutata could be mass-reared for biocontrol purposes by adopting the methods and techniques currently used for C. carnea s.l. because of the ability of both lacewings to develop and reproduce on factitious foods such as E. kuehniella eggs and their adults' non-predatory diet of sugar-rich liquids (Pappas et al., Reference Pappas, Broufas and Koveos2011; Athanasiadis et al., Reference Athanasiadis, Pappas and Broufas2021). Currently, C. carnea s.l. is the main chrysopid species used in biological control, whereas difficulties in the identification of the different species of the carnea group have been related to varying biocontrol success in the field (Tauber et al., Reference Tauber, Tauber, Daane and Hagen2000; Pappas et al., Reference Pappas, Broufas and Koveos2011; Henry et al., Reference Henry, Brooks, Duelli, Johnson, Wells and Mochizuki2013). Here, we revealed the biocontrol potential of C. agilis which is distinguishable from the other cryptic species by the distinct mating signals of adults (Henry et al., Reference Henry, Brooks, Duelli and Johnson2003; Noh and Henry, Reference Noh and Henry2010). Also, C. mutata produces different mating signals and bears distinct morphological traits from C. pudica (Duelli et al., Reference Duelli, Monserrat and Henry2019). The predation efficiency of C. carnea s.l. has been studied against different aphid and mealybug species (e.g. Hagley, Reference Hagley1989; Atlihan et al., Reference Atlihan, Kaydan and Özgökçe2004; El-Sahn and Gaber, Reference El-Sahn and Gaber2012; Shrestha and Enkegaard, Reference Shrestha and Enkegaard2013; Jessie et al., Reference Jessie, Giles, Rebek, Payton, Jessie and McCornack2015; Saljoqi et al., Reference Saljoqi, Asad, Khan, Haq, Nasir, Zada, Ahmad, Nadeem, Huma and Salim2016). To date, no study had assessed its biocontrol efficiency against M. persicae or P. solenopsis in pepper by C. agilis and C. mutata. Considering the preference of the latter for warmer and drier habitats (Canard and Thierry, Reference Canard and Thierry2013), comparative studies with the commercial C. carnea s.l. could reveal advantages of C. agilis and C. mutata in aphid and mealybug biocontrol under warm and dry conditions.

In conclusion, both C. agilis and C. mutata are predators with high potential in biological pest control. The larvae of both were shown capable of suppressing M. persicae as well as P. solenopsis populations on pepper plants for the time period of our experiments, with C. agilis being more efficient against aphids than C. mutata. Further research focusing on the life-history traits of both chrysopids under different conditions coupled with long-term greenhouse experiments with varying densities of prey and released larvae is needed to clarify the role of C. agilis and C. mutata under realistic conditions.

Acknowledgements

We thank the undergraduate students Evangelos Doulopoulos and Konstantinos Tsimourdagkas for technical help during the course of the experiments. Part of this work was funded by Biobest Group NV (project number 82083).

Author contributions

M. P., G. B., A. P. and F. W. conceived the study. G. K. and A. S. performed the experiments. M. P., G. B. and G. K. wrote the manuscript with input from A. P. and F. W. All authors read and approved the manuscript.

Conflict of interest

A. P. and F. W. are employed at Biobest Group NV. Authors declare no conflict of interest.

References

Abdulhay, HS (2021) Numerical response of predator Chrysoperla mutata MacLachlan to varying densities of Lipaphis erysimi (Kalt). Indian Journal of Ecology 48, 746748.Google Scholar
Athanasiadis, K, Pappas, ML and Broufas, GD (2021) Effect of duration of exposure to males on female reproductive performance of the green lacewing, Chrysoperla agilis (Neuroptera: Chrysopidae). Insects 12, 560.CrossRefGoogle ScholarPubMed
Atlihan, R, Kaydan, B and Özgökçe, MS (2004) Feeding activity and life history characteristics of the generalist predator, Chrysoperla carnea (Neuroptera: Chrysopidae) at different prey densities. Journal of Pest Science 77, 1721.CrossRefGoogle Scholar
Bragard, C, Di Serio, F, Gonthier, P, Jaques Miret, JA, Justesen, AF, Magnusson, CS, Milonas, P, Navas-Cortes, JA, Parnell, S, Potting, R, Reignault, PL, Thulke, HH, Van der Werf, W, Civera, AV, Yuen, J, Zappalà, L, Gregoire, JC, Malumphy, C, Campese, C, Czwienczek, E, Kertesz, V, Maiorano, A and MacLeod, A (2021) Pest categorisation of Phenacoccus solenopsis. EFSA Journal 19, e06801.Google ScholarPubMed
Brooks, SJ (1994) A taxonomic review of the common green lacewing genus Chrysoperla (Neuroptera: Chrysopidae). Bulletin of the British Museum of Natural History (Entomology) 63, 137210.Google Scholar
Brooks, SJ and Barnard, PC (1990) The green lacewings of the world: a generic review (Neuroptera: Chrysopidae). Bulletin of the British Museum (Natural History) Zoology 59, 117286.Google Scholar
Canard, M and Principi, MM (1984) Development of chrysopidae. In Canard, M, Semeria, Y and New, TR (eds), Biology of Chrysopidae. Junk: The Hague, pp. 5775.Google Scholar
Canard, M and Thierry, D (2013) The distribution of Chrysoperla mutata (McLachlan, 1898) and Chrysoperla pudica (Navás, 1914) (Neuroptera: Chrysopidae). Entomofauna 35, 289296.Google Scholar
Canard, M, Séméria, Y and New, TR (1984) Biology of Chrysopidae. The Hague: Dr W. Junk Publishers.Google Scholar
Duelli, P (2001) Lacewings in field crops. In McEwen, PK, New, TR and Whittington, AE (eds), Lacewings in the Crop Environment. Cambridge, UK: Cambridge University Press, pp. 158171.CrossRefGoogle Scholar
Duelli, P, Monserrat, VJ and Henry, CS (2019) First report of Chrysoperla mutata (Mclachlan, 1898) (Neuroptera: Chrysopidae) on the Canary Islands. Entomological News 128, 486492.CrossRefGoogle Scholar
El-Sahn, OMN and Gaber, NMA (2012) Feeding potential of Chrysoperla carnea (Stephens) on different stages of Planococcus citri (Risso) under laboratory conditions. Egyptian Journal of Biological Pest Control 22, 217221.Google Scholar
Hagley, EAC (1989) Release of Chrysoperla carnea Stephens (Neuroptera: Chrysopidae) for control of the green apple aphid, Aphis pomi Degeer (Homoptera: Aphididae). The Canadian Entomologist 121, 309314.CrossRefGoogle Scholar
Henry, CS, Brooks, SJ, Thierry, D, Duelli, P and Johnson, JB (2001) The common green lacewing (Chrysoperla carnea s. lat.) and the sibling species problem. In McEwen, PK, New, TR and Whittington, AE (eds), Lacewings in the Crop Environment. Cambridge, UK: Cambridge University Press. pp. 2942.CrossRefGoogle Scholar
Henry, CS, Brooks, SJ, Duelli, P and Johnson, JB (2003) A lacewing with the wanderlust: the European song species ‘Maltese’. Chrysoperla agilis, sp. n., of the carnea group of Chrysoperla (Neuroptera: Chrysopidae). Systematic Entomology 28, 131148.CrossRefGoogle Scholar
Henry, CS, Brooks, SJ, Johnson, JR, Wells, MM and Duelli, P (2011) Song analysis reveals a permanent population of the Mediterranean lacewing Chrysoperla agilis (Neuroptera: Chrysopidae) living in central Alaska. Annals of the Entomological Society of America 104, 649657.CrossRefGoogle Scholar
Henry, CS, Brooks, SJ, Duelli, P, Johnson, JB, Wells, MM and Mochizuki, A (2013) Obligatory duetting behaviour in the Chrysoperla carnea-group of cryptic species (Neuroptera: Chrysopidae): its role in shaping evolutionary history. Biological Reviews 88, 787808.CrossRefGoogle ScholarPubMed
Jessie, WP, Giles, KL, Rebek, EJ, Payton, ME, Jessie, CN and McCornack, BP (2015) Preference and performance of Hippodamia convergens (Coleoptera: Coccinellidae) and Chrysoperla carnea (Neuroptera: Chrysopidae) on Brevicoryne brassicae, Lipaphis erysimi, and Myzus persicae (Hemiptera: Aphididae) from winter-adapted canola. Environmental Entomology 44, 880889.CrossRefGoogle ScholarPubMed
Khuhro, NH, Chen, H, Zhang, Y, Zhang, L and Wang, M (2012) Effect of different prey species on the life history parameters of Chrysoperla sinica (Neuroptera: Chrysopidae). European Journal of Entomology 109, 175180.CrossRefGoogle Scholar
Makarkin, VN and Shchurov, VI (2019) Neuropterida and mecoptera from the north-western Caucasus. Kavkazskij Entomologiceskij Bulleten 15, 299316.Google Scholar
McEwen, P, New, T and Whittington, A (2001) Lacewings in the Crop Environment. Cambridge, UK: Cambridge University Press.CrossRefGoogle Scholar
Messelink, GJ, Vijverberg, R, Leman, A and Janssen, A (2016) Biological control of mealybugs with lacewing larvae is affected by the presence and type of supplemental prey. BioControl 61, 555565.CrossRefGoogle Scholar
Noh, S and Henry, CS (2010) Sexually monomorphic mating preferences contribute to premating isolation based on song in European green lacewings. Evolution 64, 261270.CrossRefGoogle Scholar
Pappas, ML, Broufas, GD and Koveos, DS (2007) Effects of various prey species on development, survival and reproduction of the predatory lacewing Dichochrysa prasina (Neuroptera: Chrysopidae). Biological Control 43, 163170.CrossRefGoogle Scholar
Pappas, ML, Broufas, GD and Koveos, DS (2011) Chrysopid predators and their role in biological control. Journal of Entomology 8, 301326.CrossRefGoogle Scholar
Pappas, ML, Karagiorgou, E, Papaioannou, G, Koveos, DS and Broufas, GD (2013) Developmental temperature responses of Chrysoperla agilis (Neuroptera: Chrysopidae), a member of the European carnea cryptic species group. Biological Control 64, 291298.CrossRefGoogle Scholar
Pekas, A, De Craecker, I, Boonen, S, Wäckers, FL and Moerkens, R (2020) One stone; two birds: concurrent pest control and pollination services provided by aphidophagous hoverflies. Biological Control 149, 104328.CrossRefGoogle Scholar
Saljoqi, AUR, Asad, N, Khan, J, Haq, EU, Nasir, M, Zada, H, Ahmad, B, Nadeem, M, Huma, Z and Salim, M (2016) Functional response of Chrysoperla carnea Stephen (Neuroptera: Chrysopidae) fed on cabbage aphid, Brevicoryne brassicae (Linnaeus) under laboratory conditions. Pakistan Journal of Zoology 48, 165169.Google Scholar
Shrestha, G and Enkegaard, A (2013) The green lacewing, Chrysoperla carnea: preference between lettuce aphids, Nasonovia ribisnigri, and western flower thrips, Frankliniella occidentalis. Journal of Insect Science 13, 94.CrossRefGoogle ScholarPubMed
SPSS (2020) IBM SPSS Statistics for Windows, Version 27.0.Google Scholar
Szentkirályi, F (2001) Ecology and habitat relationships. In McEwen, PK, New, TR and Whittington, AE (eds), Lacewings in the Crop Environment. Cambridge, UK: Cambridge University Press, pp. 82115.CrossRefGoogle Scholar
Tauber, MJ, Tauber, CA, Daane, KM and Hagen, KS (2000) Commercialization of predators: recent lessons from green lacewings (Neuroptera: Chrysopidae: Chrysoperla). American Entomologist 46, 2638.CrossRefGoogle Scholar
Thierry, D, Canard, M and Mirmoayedi, A (2004) Chrysoperla mutata (McLachlan, 1898) looking at the live adult, description of its larva and some bioeconomical remarks. Entomofauna 25, 345356.Google Scholar
van der Ent, S, Knapp, M, Klapwijk, J, Moerman, E, van Schelt, J and de Weert, S (2017). The biology of pests, diseases and their natural solutions. In Girard, K and Stroobach, L-A (eds), Knowing and Recognizing. Koppert B.V., Berkel en Rodenrijs, p. 443.Google Scholar
Zhang, ZQ (2003) Mites of Greenhouses: Identification, Biology and Control. Cambridge, UK: CABI Publishing.CrossRefGoogle Scholar
Figure 0

Figure 1. Experimental set-up used to evaluate the predation efficiency of larvae of C. mutata and C. agilis on pepper plants in insect cages infested by (i) M. persicae or (ii) P. solenopsis. Pest suppression was assessed 11 or 21 days after lacewing (second-instar larvae) initial release on the plants for aphids and mealybugs, respectively.

Figure 1

Figure 2. Mean number of (a) mealybugs and (b) aphids consumed by C. mutata (CM) and C. agilis (CA) third-instar lacewing larvae in 24 h in laboratory Petri dish assays (25 ± 1°C, 16:8 LD). ns: P > 0.05.

Figure 2

Figure 3. Mean number of (a) aphids 14 days (d42) after plant infestation with 100 aphid (third–fourth instar) nymphs followed by the release of C. mutata (CM) or C. agilis (CA) second-instar larvae (ten larvae were released per species twice on each plant at d31 and d35, i.e. 20 larvae in total) as compared to control (CON) plants (no lacewing release), and (b) live individuals (i.e. emerging lacewing adults and live pupae) per lacewing species in each cage, Kruskal–Wallis multiple comparison analysis with a Dunn's post-hoc test. ns,  not significant, *P < 0.05, **P < 0.01, ***P < 0.001.

Figure 3

Figure 4. Mean number of (a) mealybugs 28 days (d56) after plant infestation with one mealybug female carrying an egg-sac followed by the release of C. mutata (CM) or C. agilis (CA) second-instar larvae (per species, 15 larvae released thrice on each plant at d35, d42 and d49, i.e. 45 larvae in total) as compared to control (Con) plants (no lacewing release), and (b) live individuals (i.e. emerging lacewing adults and live pupae) per lacewing species in each cage, Kruskal–Wallis multiple comparison analysis with a Dunn's post-hoc test. ns, not significant, *P < 0.05, **P < 0.01, ***P < 0.001.