Among the pests of peanuts (Arachis hypogaea L.; Fabales: Fabaceae), the thrips, Enneothrips flavens Moulton (Thysanoptera: Thripidae), has received increasing attention because of the serious economic damage that it causes (Moraes et al. 2005; Dalastra et al. 2011; Michelotto et al. 2013). Enneothrips flavens lives in the closed buds or enclosed parts of the plant, and punctures and sucks the cell contents. Consequently, peanut buds are deformed and distorted, exhibiting streaks and discolorations, which result in major crop losses (Gallo et al. 2002). Although chemical control is frequently used, its intense and increasing application contributes to environmental contamination (Bhanti & Taneja 2007), decline of pollinators, and the development of pesticide resistance (Fournier 2005; Henry et al. 2012; Whitehorn et al. 2012). Biological control has been used as an alternative to chemical control, and in some instances it is an efficient tool for pest management (Jonsson et al. 2012).

The green lacewing, Chrysoperla externa Hagen (Neuroptera: Chrysopidae), is an important natural enemy of several pest species, because it is tolerant to some pesticides and is a voracious predator (Brettell 1982; Freitas 2001a; Rimoldi et al. 2012; Silva et al. 2012). It has been found in different agroecosystems and has shown significant potential as a biological control agent of phytophagous insects (Carvalho & Souza 2000; Freitas 2002; Bonani et al. 2009).

A growing body of research has shown the importance of releasing green lacewings as control agents for the management of pests, including thrips (Carvalho & Souza 2000). By releasing second-instar larvae of Chrysoperla carnea Stephens, Hassan (1978) demonstrated successful control of Myzus persicae Sulzer (Hemiptera: Aphididae) on eggplant (Solanum melongena L; Solanales: Solanaceae) grown in greenhouses. The apple aphid, Aphis pomi De Geer (Hemiptera: Aphididae), has been controlled by releasing eggs of C. carnea on apple cultivars (Hagley 1989). The control of various pests in North America by augmentative release of C. carnea has been reported. In cotton, C. carnea has suppressed Helicoverpa zea Boddie (Lepidoptera: Noctuidae) and Heliothis virescens (F) (Lepidoptera: Noctuidae) (Ridgway & Jones 1969), and, as also demonstrated with C. rufilahris, has significantly suppressed the thrips Scritothrips citri Moulton (Thysanoptera: Thripidae) on mango (Khan & Morse 2001).

This study investigated the efficacy of using C. externa against E. flavens, for reducing the latter's population size in response to the release of C. externa eggs and larvae onto peanut plants grown in a greenhouse.

Materials and Methods

Statistical Analysis

There was wide variability among the treatments and within each treatment (Fig. 1). Given the dependence of the observations taken in the same experimental unit over time, the nonlinear behavior of the data, as well as the assumption that the mean number of thrips per plant decreases over time, an asymptotic mixed-effects regression model (Pinheiro & Bates 2000) was used. This model can be written as:

where y_ijk is the mean number of thrips (Table 1) for the i-th treatment, j-th replicate, and k-th time period, Φ_1i is the asymptote for the i-th treatment, Φ_2i is a scaling parameter for the i-th treatment, b_2ij. ∼ N(0, σ²_b2 is the random effect associated with φ_2i, Φ_3i is logarithm of the rate constant for the i-th treatment, t_k is the time and ε_ijk is the error.

Table 1.

Mean number of Enneothrips flavens (nymphs and adults) found in closed Arachis hypogaea Buds in 3 treatments: Control A. Hypogaea plants (without Chrysoperla externa), on A. Hypogaea plants that received C. Externa eggs, and on A. Hypogaea plants that received C. externa Larvae.

To test for treatment differences, two submodels, namely M2 and M3, were fitted to the data. In M2, the T2 (C. externa eggs) and T3 (C. externa larvae) treatments were grouped; and in M3, the linear predictor is given by

that is, no treatment effect was assumed. The models were compared using likelihood-ratio tests (Verbeke & Molenberghs 2000).

Model M2 did not differ statistically from model M1, and so treatments T2 (C. externa eggs) and T3 (C. externa first-instar larvae) did not differ statistically (p = 0.05), see Table 2. Also, model M3 fit the data poorly compared to model M2 (Table 2). Therefore, the control treatment differed from the T2 and T3 group (p = 0.05).

The parameter Φ₃ estimate for treatments T2 and T3 was not significant (F_1,171 = 0.10, p = 0.75), so two submodels were fitted to the data: model M 4 with a linear predictor given by

that is, parameter Φ₃ is the same for all treatments; and model M5, with the linear predictor given by

Table 2.

Likelihood-ratio tests for nested models M1, M2 AND M3.

Table 3.

Likelihood-ratio tests for nested models M2, M4 and M5.

that is, parameter Φ₃ is set to zero. The likelihood-ratio tests (Table 3) showed that the fit from model M4 did not differ from that of model M2; however, the fit of model M5 was significantly different (Table 2). Therefore, model M4 fit the data as well as model M2 and could be used as a final model.

Table 4 shows the parameter estimates and associated standard errors for model M4, which can be written as

Results and Discussion

On day zero, each control plant had a mean of 7.75 thrips, the plants that subsequently received C. externa eggs had 11.85 thrips/plant, and the group that subsequently received lace wing larvae had 13.90 thrips/plant (Table 1). The passage of time did not influence the population of thrips in the control, but there were significant differences in the effects of C. externa releases over time on thrips densities at 0 to 4, 9 and 15 days post-release (Figs. 1 and 2).

Table 4.

Parameter estimates (standard errors) FOR MODEL M4 (Φ₁ is the asymptote, Φ₂ is a scaling parameter, Φ₃ is logarithm of the rate constant and σ²₈₂ is the variance of the random effect associated with Φ₂)

These results suggest that C. externa requires some time after being released in order to show significant impacts on the pest population. On the sampling dates, the mean number of E. flavens thrips was significantly reduced on plants that had received C. externa when compared with the control plants. These results provided evidence for the potential of C. externa as a biological control agent of E. flavens, under specific conditions on potted peanuts in a greenhouse. The statistical modeling confirmed that the thrips population decreased in the presence of C. externa, as shown in Fig. 1. This result is easily observed by comparing the 2 trends, the constant line describing the E. flavens population in the control and the curves describing the E. flavens populations under the influence of C. externa that had been released either as eggs or larvae (Figs. 1 and 2).

In the absence of predators, it is expected that the mean number of thrips in closed peanut buds will increase, as seen with M. persicae aphids on eggplants (Hassan 1977). In the current study, the number of E. flavens thrips in the control remained stable, while in the other treatments the number was reduced. On day 15, C. externa third-instars started to pupate, and in response the thrips population increased slightly. It is important to use appropriate intervals between predator releases, in order to prevent the pest from persisting when the C. externa larvae are in a post-feeding period. The appropriate release intervals for the control of M. persicae by C. carnea have been estimated from 2 to 5 weeks (Hassan 1977). However, for E. flavens these release intervals would vary from 9 to 15 days, based on the results of the current study.

Fig. 1.

Biological control of Enneothrips flavens with Chrysoperla externa, showing daily trends in each of 20 replicates. The control consisted of Enneothrips flavens thrips-infested peanut plants that received no Chrysoperla externa individuals. In treatment T2 the thrips-infested peanut plants received 4 C. externa eggs/plant, and in treatment T3 the thrips-infested peanut plants received 3 newly hatched C. externa first-instar larvae/plant.

A few studies involving the genus Chrysoperla and thrips have been designed to investigate preferences between different prey. In a recent study, Shrestha & Enkegaard (2013) analyzed the prey choice by 3rd-instar C. carnea on the western flower thrips Frankliniella occidentalis and the lettuce aphid Nasonovia ribisnigri (Mosley) (Aphididae) in the laboratory, by using different prey ratios. The results of the study suggest a slight preference of C. carnea for aphids compared to thrips. However, the results were also significantly influenced by the predator-prey ratios; and at some ratios, no preference was observed (Shrestha & Enkegaard 2013). Although this result indicated an apparent weak interaction between C. carnea and thrips, survey results have shown that members of the genus Chrysoperla are frequently present on plants of different species containing thrips (Bettiol et al. 2004; Mann et al. 2010; Saeidi & Adam 2011), encouraging studies to evaluate the probable interaction dynamics between these species. Unfortunately, the lack of studies investigating possible interactions between populations of C. externa and E. flavens make any specific comment about the interaction strength between them impossible. To our knowledge, studies examining the biological control of E. flavens are not common, and ours is a pioneer study on the use of C. externa for this purpose.

Fig. 2.

Reduction of Enneothrips flavens on peanut plants by Chrysoperla externa. The average (± SE) numbers of thrips per peanut plant were fitted the curve using model M4. The control consisted of Enneothrips flavens thrips-infested peanut plants that received no Chrysoperla externa individuals. In treatment T2 the thrips-infested peanut plants received 4 C. externa eggs/ plant, and in treatment T3 the thrips-infested peanut plants received 3 newly hatched C. externa first-instar larvae/plant.