Abstract
The possible interference of resistant pest’s populations to insecticides in natural enemies in the action thas not been clarified yet. Thus, this study aimed to evaluate Trichogramma pretiosum Riley (Hymenoptera: Trichogrammatidae) performance on Spodoptera frugiperda (J. E. Smith) (Lepidoptera: Noctuidae) eggs with resistance frequency to the Metaflumizone over six generations of product exposure. Egg cards (2.0 x 7.0 cm) containing eggs from two populations of S. frugiperda, (resistant to Metaflumizone and the other susceptible), were exposed to T. pretiosum females for 24 hours in free-choice and no-choice testing in three generations (G1, G4, and G6). A completely randomized experimental design was used with 25 replications, each consisting of an egg card (experimental unit) containing 20 eggs. The parameters evaluated were: parasitism (%), emergence (%), sex ratio, number of emerged parasitoids per egg and males/females longevity. ANOVA and Tukey test (P≤ 0.05) were applied on the results. Results showed a reduction in parasitism [41.0% (G1) and 28.4% (G4)], egg emergence (17.5%) and parasitoids/egg [16.2 (G4) and 17.2 (G6)] in eggs originating from the population with resistance frequency. Females emerging from G6 populations eggs without exposure to Metaflumizone had greater longevity (3.5 days more) than the resistant population. The sex ratio and male longevity were not affected. The results indicate a reduction in T. pretiosum activity if S. frugiperda populations have some frequency of resistance to Metaflumizone.
Keywords: biological control; fitness cost; insect resistance; parasitism; Spodoptera frugiperda
Resumo
A possível interferência de populações de pragas resistentes na ação de inimigos naturais ainda não foi esclarecida. Assim, este trabalho teve como objetivo avaliar o desempenho de Trichogramma pretiosum Riley (Hymenoptera: Trichogrammatidae) em ovos de Spodoptera frugiperda (J. E. Smith) (Lepidoptera: Noctuidae) com frequência de resistência à Metaflumizona ao longo de seis gerações de exposição ao produto. Cartelas (2,0 x 7,0 cm) com ovos de duas populações de S. frugiperda, (resistente à Metaflumizona e outra suscetível), foram expostas às fêmeas de T. pretiosum por 24 horas em condições de livre escolha e sem chance de escolha por três gerações (G1, G4 e G6). O delineamento experimental foi inteiramente casualizado com 25 repetições, sendo cada repetição composta por uma cartela (unidade experimental) contendo 20 ovos. Os parâmetros avaliados foram: parasitismo (%), emergência (%), razão sexual, número de parasitoides emergidos por ovo e longevidade de machos e fêmeas. ANOVA e teste de Tukey (P≤ 0,05) foram aplicados aos dados coletados. Os resultados mostraram redução do parasitismo [41,0% (G1) e 28,4% (G4)], emergência de ovos (17,5%) e parasitoides/ovo [16,2 (G4) e 17,2 (G6)] em ovos oriundos da população com frequência de resistência. As fêmeas emergidas de ovos da população G6 sem exposição à Metaflumizona, tiveram maior longevidade (3,5 dias a mais) do que a população exposta ao inseticida. A razão sexual e a longevidade de machos não foram afetadas. Os resultados indicam uma redução na atividade de T. pretiosum se as populações de S. frugiperda apresentarem alguma frequência de resistência à Metaflumizona.
Palavras-chave: controle biológico; custo adaptativo; resistência de insetos; parasitismo; Spodoptera frugiperda
1. Introduction
In spite of the diversity of control techniques, insecticides also constitute the basis of management practices to reduce damage caused by Spodoptera frugiperda (J. E. Smith) (Lepidoptera: Noctuidae). However, adoption of a control strategy with solely on systematic applications of insecticides without rotation of active ingredients is bound to fail (Furlong et al., 2004; IRAC, 2021), leading to an increase in the percentage of damage due to the selection of resistant populations. Considering this situation, the adoption of some strategies that retard or reduce the development of resistance, associated with changes in the conception and behavior of growers, is of utmost importance.
Among the management practices inserted in a context of Integrated Pest Management (IPM), the natural enemies as the basis of practices for effective control of pest arthropods has been widely recognized (Furlong, 2015). In the case of S. frugiperda, control has been carried out through release of parasitoids of the genus Trichogramma spp. (Hymenoptera: Trichogrammatidae) (Beserra et al., 2005; Dequech et al., 2013; Figueiredo et al., 2015; Balestrin and Bordin, 2016) that are used in programs of applied biological control since these agents parasitize the egg phase of the pest and impede the emergence of caterpillars and thus does not occur their attack. In Brazil, the natural occurrence of Trichogramma pretiosum Riley (Hymenoptera: Trichogrammatidae) parasitizing eggs of S. frugiperda (Beserra et al., 2002; Dequech et al., 2013; Balestrin and Bordin, 2016) offers good perspectives for its application because, in addition to its ability to act on the target pest, this parasitoid is easily rearing in the laboratory conditions.
Nevertheless, for this natural enemy to be effectively used, its activity, behavior, and efficiency must be understood (Barbosa et al., 2019) in its host. It is known that females of these parasitoids have strategies that facilitate identification of a quality host through surface contact of antennas (Bento and Nardi, 2012). Thus, the sequence of the activities of search and recognition behavior assist the female in identifying specific chemical or physical signs of the host; this helps in the decision of accepting the host or not for oviposition or even identifying if the host is nutritionally adequate or is sufficient for complete development of its offspring (Roriz et al., 2006; Brotodjojo and Walter, 2006).
In a biological control program, the capacity of the parasitoid to parasitize or develop in the host is a crucial step, because the existence of some characteristic that avoids oviposition or inhibits development of the parasitoid can cause failure in parasitism and, consequently, in control of the pest (Pereira et al., 2013). It is not known if physiological and metabolic changes involved in the process of evolution of resistance (Dingha et al., 2004; Guedes et al., 2006) affect specific characteristics of the host that interfere in the recognition and establishment processes of parasitoids. Thus, possible interferences of populations with frequency of resistance to insecticides on the action of natural enemies have not yet been duly clarified. Although T. pretiosum is highly used in biological control programs throughout the world, information is still scarce in regard to its activity and efficiency, as well as how the biological characteristics of its offspring are affected when they find eggs of hosts that have a certain resistance to some insecticide. Such studies should be carried out to develop knowledge regarding the association of T. pretiosum in control of pests that have resistance to insecticides, and regarding recommendation of T. pretiosum in these cases.
Thus, the aim of this study was to evaluate the performance of T. pretiosum on eggs of populations of S. frugiperda with frequency of resistance to the insecticide Metaflumizone and exposure to the product over six generations.
2. Material and Methods
The experiment was conducted in the “Laboratório de Entomologia Aplicada - LEA” of the “Universidade Federal do Ceará (UFC)”, Fortaleza, Ceará State, Brazil. The “guaraciaba” line of T. pretiosum used was collected when naturally parasitizing eggs of Neoleucinodes elegantalis (Guenée) (Lepidoptera: Crambidae) on tomato (Solanum lycopersicum L.) fruit (Oliveira et al., 2020). The population of S. frugiperda with frequency of resistant individuals was collected in commercial areas in the municipality of Quixeré, Ceará (Latitude 5°4′40′′S, Longitude 7°59′7″W, and mean Altitude of 25.0 m AMSL), with mean maximum temperature of 35.0°C and mean minimum of 22.0°C. The system used to rearing T. pretiosum followed the method described by Parra (1997).
The experiment was conducted with eggs from two populations of S. frugiperda (one resistant population maintained under selection pressure for resistance to metaflumizone and the other without exposure to the product, considered the susceptible population), over six generations. The characterization of the resistance frequency of the populations used is described in Barbosa et al. (2020). The Metaflumizona, semicarbazone chemical group, is sodium channel inhibitor (SCI) insecticides by binding selectively to slow-inactivated (non-conducting) sodium channel states (Takagi et al., 2007; Song et al., 2011). No-choice (G1, G4, and G6) and free-choice (only in G6) trials were carried out. Both populations were kept in the laboratory in glass tubes (2.5 cm x 8.5 cm), containing an artificial diet (Greene et al., 1976).
To conduct the experiment, eggs from each population were placed on blue paperboard cards (8.0 x 2.5 cm) using gum arabic (30%) with the assistance of a moistened brush. In the no-choice test, each egg card (experimental unit) was composed of 20 eggs from one of the two populations. In the free-choice test, each egg card was composed of 10 eggs from both populations, for a total of 20 eggs per treatment. Before being offered to the parasitoids, the eggs were made inviable through exposure to a germicidal lamp for 30 minutes, preventing possible eclosion of non-parasitized caterpillars and loss of data since the caterpillars are cannibalistic.
The cards containing inviable eggs from one of the two populations in separation (no-choice cards) or containing inviable eggs from the two populations on the same card (free-choice cards) were inserted in glass tubes (8.5 x 2.5 cm) containing a female parasitoid, where they remained exposed to parasitism for 24 hours. The tubes were closed with PVC plastic film to prevent the parasitoids from escaping. The female parasitoids were fed with a drop of pure honey placed on the wall of the tubes. After exposure, the cards were transferred to new glass tubes (8.5 x 2.5 cm) and they were placed under controlled conditions (25 ± 2°C, relative humidity of 70±10% and 12-hour photoperiod), remaining up to emergence of the following generation of the parasitoids.
The percentage of parasitism [(number of parasitized eggs / total number of eggs) x 100], percentage of emergence [(number of dark eggs with orifice / total number of parasitized eggs) x 100], sex ratio [number of emerged females / (number of females + males)], number of emerged parasitoids per egg (number of emerged parasitoids / total number of parasitized eggs), and the longevity (days) of males and females were the parameters evaluated in the no-choice test. For evaluation of this last parameter, 20 females and 10 males that had recently emerged were individualized in acrylic containers (3.5 x 1.5 cm) containing a drop of honey for food, and they were evaluated daily regarding time of life. In the free-choice test, performed in G6, only the percentage of parasitism and of emergence were evaluated.
The experiments were conducted in a completely randomized experimental design, with 25 replications; each replication consisted of an egg card containing 20 eggs. The data were submitted to the Shapiro-Wilk normality and Bartlett parametric variance homogeneity tests. ANOVA was used to analyze the data and the means were compared by the Tukey test (p≤ 0.05) through the Statistical Analysis System (SAS) (SAS INSTITUTE, 2004).
3. Results
Parasitism of S. frugiperda eggs by T. pretiosum decreased in populations that were sequentially exposed to the insecticide Metaflumizone (G1 and G4), with reduction of approximately 41.0% and 28.4% (Table 1). In regard to emergence, 82.7% of the eggs of the population exposed to the insecticide, when parasitized, allowed emergence of the adults of the parasitoid but, even so, there was reduction of 17.5% compared to the control (Table 1).
Parasitism (%); emergence (%); sex ratio; number of adults emerged per egg; longevity (days) of T. pretiosum “guaraciaba” line, in eggs of two populations of S. frugiperda over six generations in a no-choice test.
Emergence of more than one parasitoid per egg was found in both host populations evaluated (minimum of 1.02 and maximum of 1.32 parasitoids / egg); however, there was a decrease of 16.2% and 17.2% when the populations were exposed to the insecticide in G4 and G6, respectively (Table 1).
Females of T. pretiosum that emerged from eggs coming from populations in G6 maintained without exposure to the insecticide Metaflumizone lived longer; longevity was 3.5 days longer for these females than that of the population exposed to the product (Table 1). Regarding longevity of the males, only an effect of the generation factor was observed, with a mean of 5.6 in G1 and 9.40 days in the G4 and G6 generations (Table 1).
The longevity of males and the sex ratio were not affected by the populations evaluated, and exhibited a variation from 5.50 to 10.26 and 0.51 to 0.75, respectively (Table 1).
In the free-choice test, there was a reduction in the percentage of parasitism of S. frugiperda and of emergence of T. pretiosum adults of 16.3% and 24.1%, respectively, in the trial with the S. frugiperda population resistant to the insecticide Metaflumizone (Table 2).
Parasitism (%) and emergence (%) of T. pretiosum “guaraciaba” line, in eggs of two populations of S. frugiperda in a free-choice test in G6.
4. Discussion
Based on the results obtained and on knowledge regarding the behavior of T. pretiosum in regard to host selection, it can be inferred that female parasitoids rejected the “resistant” S. frugiperda host in the tests of free choice and no choice; and the eggs of this host, when parasitized, affected parameters related to the development of the offspring of T. pretiosum. The exploratory characteristic of the parasitoid species (Roriz et al., 2006; Brotodjojo and Walter, 2006) indicates that the females of T. pretiosum, distinguished differences in the host eggs and consequently rejected them in some moment by means of some external or internal signal present in the host egg coming from individuals that developed under the conditions of exposure to the insecticide. In initial contact with the host eggs, signals are recognized by the antennas, and for insertion of the ovipositor, the females need to perfectly evaluate the external and internal conditions of the host eggs (Desneux et al., 2012; Alsaedi et al., 2016; Damien et al., 2019). This evaluation determines acceptance or non-acceptance of the host for oviposition, according to its nutritional quality (Roriz et al., 2006), ensuring the success of the offspring of the parasitoid (Roriz et al., 2006; Brotodjojo and Walter, 2006)
Synergy trials conducted in populations of Spodoptera exigua (Hübner) (Lepidoptera: Noctuidae) showed that resistance to Metaflumizone is associated with metabolic changes involving an increase in esterase (Su and Sun, 2014; Tian et al., 2014) and monooxygenase (Tian et al., 2014) activity. It is nothing new that these changes can result in an adaptive cost associated with resistance (Gould, 1998), where resources used by the physiological processes of the insect are allocated and used in a different manner, influencing metabolic processes and development in resistant lines and in evolution (Dingha et al., 2004; Guedes et al., 2006). The adaptive cost has already been observed in S. frugiperda resistant to the insecticides and resistance plants (Santos-Amaya et al., 2017; Okuma et al., 2018), and also in Plutella xylostella (Linnaeus) (Lepidoptera: Plutellidae) resistant to Metaflumizone (Shen et al., 2017). This indicates that, as resistance evolves, these metabolic changes can modify components in the chorion (egg membrane) or in its inner content, affecting the development of the parasitoid larvae and leading to reduction in emergence in the number of parasitoids / egg, and in the longevity of emerged females.
The number of parasitoids per egg that emerged from the population of S. frugiperda exposed to Metaflumizone was lower than the number of parasitoids per egg that emerged from the susceptible population. The surface contact and recognition of the host (Roriz et al., 2006; Brotodjojo and Walter, 2006) may have resulted in rejection of females in laying more than one egg in the host given the possibility of it not being able to ensure development of its offspring. The sign of a larger number of parasitoids / egg and of longer-living females of T. pretiosum in contact with the susceptible population shows that this parasitoid has greater probability of increasing its population in a shorter period of time than the T. pretiosum population in contact with S. frugiperda exposed to Metaflumizone.
Resistance to insecticides occurs through mutations that substitute alleles (Thomazoni, 2012), and selection pressure promotes genotypic variation from the initial population (Roush and Mckenzie, 1987). Studies performed with P. xylostella suggest an effect on parasitism of Diadegma semiclausum (Hellen) (Hymenoptera: Ichneumonidae) and of Cotesia plutellae (Kurdjumov) (Hymenoptera: Braconidae) when the caterpillars exposed to parasitism come from host populations that have resistance to the insecticide teflubenzuron (Furlong and Wright, 1993). In contrast, possible effects were not found in Campoletis flavicincta (Ashmead) (Hymenoptera: Ichneumonidae) acceptance of S. frugiperda caterpillars susceptible and resistant to lambda-cyhalothrin (Thomazoni, 2012).
A noteworthy fact is that even with negative interference in parasitism of T. pretiosum caused by the eggs coming from the population of S. frugiperda that showed frequency of resistance, the parasitoid still maintained satisfactory performance, with a mean value greater than 70.0%. This shows the potential of this agent in reducing the damage caused by S. frugiperda even if the population has a certain degree of resistance to metaflumizone, thus emphasizing its use as a strategy that favors management of resistance to insecticides. It should also be emphasized that in the field, there is a “coevolutionary” process that integrates parasitoids × hosts (Henter and Via, 1995), which cannot be evaluated in the laboratory under the same conditions as in the field, due to its complexity. Thus, the interference in the biological parameters examined was expressed in the most extreme condition. In a scenario where there are possibilities of development of physiological resistance on the part of the host, the parasitoids develop some manners of counter-attacking this resistance as time passes (Debolt, 1991). The reduction in parasitism in the population of S. frugiperda exposed to metaflumizone occurred in the first two generations and in artificially selected populations. It is known that through genetic drift, populations maintained in the laboratory can undergo changes associated with genetic control, resulting in effects of selection in existing genotypes and random loss of genotypes (Bartlett, 1985).
The results obtained in this study contribute useful information for planning possible management strategies for the purpose of retarding development of resistant populations of S. frugiperda. The interference observed in the performance of T. pretiosum highlights the importance of how erroneous use of insecticides can hurt the activity of natural enemies. However, T. pretiosum can still be successfully used in management programs within IPM because this parasitoid maintains its effectiveness even when in the presence of resistant populations in the field. The possibility of reversal of susceptibility when the use of insecticides is adopted in a correct manner (Barbosa et al., 2020) shows signs that joining diverse tactics in MRI can retard the evolution of frequency of resistance.
Acknowledgements
To “Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)”, “Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)” and the “Fundação Cearense de Apoio ao Desenvolvimento Científico e Tecnológico (FUNCAP)” for the study scholarships.
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Publication Dates
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Publication in this collection
11 Oct 2021 -
Date of issue
2023
History
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Received
04 Nov 2020 -
Accepted
07 June 2021