The use of toxic baits for the suppression of Mediterranean fruit fly in mango orchards

BARONIO, CLÉBER ANTONIO; MACHOTA JUNIOR, RUBEN; NUNES, MARCELO Z.; PARANHOS, BEATRIZ A.J.; BERNARDI, DANIEL; GARCIA, FLÁVIO ROBERTO M.; BOTTON, MARCOS

doi:10.1590/0001-3765202320191046

Abstract

Ceratitis capitata (Wiedemann, 1824) is an insect of major economic importance in the mango orchards of the submedium of the São Francisco River Valley, the main area of mango production and exportation in Brazil. To provide alternatives for the management of C. capitata, toxic baits based on alpha-cypermethrin (Gelsura®) and spinosad (Success® 0.02 CB) were evaluated in three commercial mango experiments during two consecutive harvests: 2016/2017 (experiment 1 - area 1) and 2017/2018 (experiment 2 -area 2 and experiment 3 - area 3). According to the results, there was a large reduction in the infestation of C. capitata after five sequential applications of the alpha-cypermethrin (6 g.ha^-1) and spinosad (0.38 g.ha^-1) toxic baits performed at seven-day intervals during mango fruit ripening in all experiments and years (harvest) evaluated. Compared with the untreated plots, the plots with alpha-cypermethrin and spinosad applications showed a significant reduction in the damage induced (fallen fruits and/or on trees) by C. capitata. The management of C. capitata in mango orchards can include the use of the toxic bait based on alpha-cypermethrin, which represents an alternative to rotate with spinosad toxic bait in the São Francisco River Valley.

Key words
Ceratitis capitata; attract & kill; alpha-cypermethrin; spinosad; chemical control

INTRODUCTION

The Mediterranean fruit fly (medfly) Ceratitis capitata (Wiedemann, 1824) (Diptera: Tephritidae) is considered a main insect pest species of mango in Brazil (Malacrida et al. 1998MALACRIDA AR, MARINONI F, TORTI C, GOMULSKI LM, SEBASTIANI F, BONVICINI C, GASPERI G & GUGLIELMINO CR. 1998. Genetic aspects of the worldwide colonization process of Ceratitis capitata. J Hered 89: 501-507., McQuate & Liquido 2017MCQUATE GT & LIQUIDO NJ. 2017. Host Plants of Invasive Tephritid Fruit Fly Species of Economic Importance. Int J Plant Biol Res 5: 1072.). The São Francisco River Valley region, located in the states of Bahia and Pernambuco, is considered the main mango production center (Ferreira et al. 2010FERREIRA MDP, LIRIO VS & MENDONÇA TG. 2010. Análise do perfil e grau de incidência de barreiras não-tarifárias sobre as exportações brasileiras de frutas selecionadas. Revista Econômica do Nordeste 41: 683-698., Silva et al. 2014SILVA AC, SOUZA AP & LEONEL S. 2014. Growth and flowering of five mango cultivar under subtropics conditions of Brazil. Amer J Plant Sci 5: 393-402.). Currently, the management of C. capitata adults and larvae has been carried out mainly with the use of organophosphate insecticides (Navarro-Llopis et al. 2013NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482., Harter et al. 2015, Botton et al. 2016BOTTON M, ARIOLI CJ, MACHOTA R, NUNES MZ & ROSA JM. 2016. Moscas-das-frutas na fruticultura de clima temperado: situação atual e perspectivas de controle através do emprego de novas formulações de iscas tóxicas e da captura massal. Agropecuária Catarinense 29: 103-108.). Additionally, due to their broad spectrum and rapid action on fruit flies, organophosphate insecticides were once the most common insecticides in toxic bait formulations (Stark et al. 2004STARK JD, VARGAS R & MILLER N. 2004. Toxicity of spinosad in protein bait to three economically important tephritid fruit fly species (Diptera: Tephritidae) and their parasitoids (Hymenoptera: Braconidae). J Econ Entomol 97: 911-915., Ruiz et al. 2008RUIZ L, FLORES S, CANCINO J, ARREDONDO J, VALLE J, DIAZ-FLEISCHER F & WILLIAMS T. 2008. Lethal and sublethal effects of spinosad-based GF-120 bait on the Tephritid parasitoid Diachasmimorpha longicaudata (Hymenoptera: Braconidae). Biol Control 44: 296-304.). However, the marketing of some of the major systemic organophosphorus insecticides has been banned, mainly because of concern for human health and the environment (Raga and Sato 2011, Morelli et al. 2012MORELLI R, PARANHOS BAJ & COSTA MLZ. 2012. Eficiência de Etofenproxi e Acetamiprido no controle de mosca-do-mediterrâneo Ceratitis capitata (Diptera: Tephritidae) em pomar de manga. Bioassay 7: 1-6., Botton et al. 2016BOTTON M, ARIOLI CJ, MACHOTA R, NUNES MZ & ROSA JM. 2016. Moscas-das-frutas na fruticultura de clima temperado: situação atual e perspectivas de controle através do emprego de novas formulações de iscas tóxicas e da captura massal. Agropecuária Catarinense 29: 103-108.). Due to these aspects related to environmental management and damage, it is necessary to search for and develop new strategies for the management of fruit flies.

It is known that in Integrated Pest Management (IPM) in mango orchards, cultural practices such as orchard sanitation, and other tactics including ‘attract & kill’ and mass trapping has been successful in suppressing the C. capitata population in mango orchards (Morelli et al. 2012MORELLI R, PARANHOS BAJ & COSTA MLZ. 2012. Eficiência de Etofenproxi e Acetamiprido no controle de mosca-do-mediterrâneo Ceratitis capitata (Diptera: Tephritidae) em pomar de manga. Bioassay 7: 1-6., Cook & Fraser 2015COOK DC & FRASER RW. 2015. Erradication versus control of Mediterranean fruit fly in Western Australia. Agr Forest Entomol 17: 173-180., Navarro-Llopis et al. 2015NAVARRO-LLOPIS V, PRIMO V & VACAS S. 2015. Bait station devices can improve mass trapping performance for the control of the Mediterranean fruit fly. Pest Manag Sci 71: 923-927.). However, it has been established that the use of toxic baits can be a useful tool in the management of C. capitata (Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... ), as verified for Anastrepha fraterculus (Weidemann, 1830) (Diptera: Tephritidae) (Harter et al. 2015), without the need for insecticide application (Navarro-Llopis et al. 2013NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482.).

These management strategies is used by producers and growers of São Francisco River Valley mango orchards, who usually spray the ready-to-use toxic bait Success® 0.02 CB (0.24 g. L^-1 spinosad) (= GF-12⁰® NF), as performed in other countries (Mangan & Moreno 2009MANGAN RL & MORENO AMT. 2009. Honeybee foraging preferences, effects of sugars and fruit fly toxic bait components. J Econ Entomol 102: 1472-1481.). However, a new toxic bait formulation, Gelsura® (6.0 g.L^-1 alpha-cypermethrin), is in the process of registration for the management of fruit flies in Brazil, with promising results for the management of fruit flies (Jang et al. 2005JANG EB, KHRIMIAN A, HOLLER TC, CASANA-GINER V, LUX S & CARVALHO LA. 2005. Field response of Mediterranean fruit fly (Diptera: Tephritidae) to Ceralure B1: evaluations of enantiomeric B1 ratios on fly captures. J Econ Entomol 98: 1139-1143., Navarro-Llopis et al. 2011NAVARRO-LLOPIS V, ALFARO C, PRIMO J & VACAS S. 2011. Response of two Tephritid species, Bactrocera oleae and Ceratitis capitata to different emission levels of pheromone and parapheromone. Crop Prot 30: 913-918., Reynolds et al. 2016REYNOLDS OL, OSBORNE T, CRISP P & BARCHIA IM. 2016. Specialized pheromone and lure application technology as an alternative male annihilation technique to manage Bactrocera tryoni (Diptera: Tephritidae). J Econ Entomol 109: 1254-1260., Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... , Vargas et al. 2018VARGAS RI, SOUDER SK, RENDON P & MACKEY B. 2018. Suppression of Mediterranean fruit fly (Diptera: Tephritidae) with trimedlure and biolure dispensers in Coffea arabica (Gentianales: Rubiaceae) in Hawaii. J Econ Entomol 111: 293-297.). Thus, the objective of this work was to evaluate the effectiveness of toxic baits based on alpha-cypermethrin and spinosad in the management of C. capitata on mango orchards.

MATERIALS AND METHODS

Three experiments were carried out on mango (Mangifera indica L.) orchards on three different farms, during two consecutive harvests: 2016/2017 and 2017/2018, located in the municipality of Casa Nova, BA (9°23’41”S; 40°44’55”W – Area 1), and the other two in Petrolina, PE (9°10’57”S; 40°31’07”W – Area 2 and 3), respectively. On each farm, we selected 6.0 ha of ‘Kent’ and ‘Tommy Atkins’ plants, with 5.0 m between plants and 7.0 to 8.0 m between rows. Previous studies have demonstrated that in the submedium of San Francisco River Valley, C. capitata infestations occur at high levels in mango orchards throughout the year.

Treatments

For C. capitata suppression in mango, the following two toxic bait formulations were used: Treatment 1 (T1): Gelsura® (alpha-cypermethrin) at 6.0 g.ha^-1 - 3.0 L.ha^-1 spray solution) (Basf SA, São Paulo, Brazil) and Treatment 2 (T2) Success® 0.02 CB (spinosad) at 0.38 g.ha^-1 - spray solution) (Dow AgroSciences Industrial Ltda. São Paulo, Brazil). As a negative control (Treatment 3 - T3), an area was not treated with any insecticide to manage C. capitata. The Gelsura® toxic bait was prepared at a ratio of 1 part commercial product to 2 parts water (volume by volume, v/v) in a similar manner to the Success® 0.02 CB toxic bait (1:1.5).

Field Experiments

Three experiments in the field were evaluated during two consecutive harvests: 2016/2017 (Area 1 - experiment 1) and 2017/2018 (Area 2 - experiment 2 and Area 3 - experiment 3). The experiment (area) 1 (2016/2017) was carried out in 3.0 ha of a 10-year-old ‘Tommy Atkins’ mango tree orchard (330 plants per hectare) located in Petrolina, PE. The treatments evaluated were: T1 - Gelsura®, T2 - Success® 0.02 CB or T3 - control treatment without application. The toxic baits were applied after the first catch in the monitoring traps to ensure that C. capitata adults were in each plot and in five sequential applications at 7-day intervals following the methodology proposed by Baronio et al. (2018)BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... . The spray jets were applied to every plant spaced 33 m² from the previous plant and directed to the trunk bifurcation located approximately 1.5 m high to form a cluster of drops at a specific point. The Gelsura® toxic bait volume per jet was 10 mL (3.0 L.ha^-1 of spray solution) and the Success® 0.02 CB toxic bait was 13.3 mL (4.0 L.ha^-1 of spray solution), based on previous experiments, for a total of 300 points per hectare for both formulations. The experimental design was a randomized complete block design, with three treatments containing four replicates (0.25 ha) per treatments.

The experiment (area) 2 and experiment (area) 3 (2017/2018), were carried out in a 6.0 ha area (density of 300 plants per hectare) located in Petrolina, PE, in a 6-year-old ‘Kent’ mango orchard and 6.0 ha area (of 350 plants per hectare) located in the municipality of Casa Grande, BA, in an 8-year-old ‘Tommy Atkins’ mango orchard, respectively. The treatments evaluated were: T1 - Gelsura®, T2 - Success® 0.02 CB or T3 - control treatment without application for each area of study (experiment 2 and experiment 3). The experimental design was a randomized complete block design, with three treatments containing four replicates (0.5 ha per repetition) per treatments and area (experiment 2 and experiment 3).

Monitoring of C. capitata adults

In all treatments and repetitions, four Jackson traps were baited with the parapheromone trimedlure (Iscalure® TML-plug, Isca Tecnologias Ltda., Ijuí, RS, Brazil), following the methodology proposed by Baronio et al. (2018)BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... . The level of the C. capitata population determined every week from prematuration until the physiological maturation of the mangoes (Rodrigues et al. 2013RODRIGUES, JC, SOUZA PJOP & LIMA RT. 2013. Estimativa de temperaturas basais e exigência térmica em mangueiras no Nordeste do Estado do Pará. Rev Bras Frutic 35: 143-150.). The number of C. capitata adults captured in the Jackson traps in the experimental areas was determined weekly after the application of toxic bait at 35, 28, 21, 14, 7 and 0 days before harvest (DBH), following the methodology proposed by Baronio et al. (2018)BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... in grape orchards. Treatment traps were placed ≈5 m apart and hung from mango plants. All flies captured in monitoring traps were removed from traps weekly, emptied into individually identified paper bags and counted in the laboratory.

Evaluation to injuries in mango fruits

For evaluate the damage caused by C. capitata larvae and the oviposition spots (oviposition punctures) caused by C. capitata females in in the fruits, were collected tirty fallen fruits from in the two central rows of each repetition. Similarly, in each repetition we evaluated the occurrence of punctures in 30 previously marked fruits. The evaluation of the damage caused by C. capitata was performed at 14, 7 and 0 DBH as described by Baronio et al. (2018)BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... .

Statistical analysis

The data obtained from the weekly capture of adult male C. capitata in the different treatments were transformed into log complement to meet the normality assumptions, using the Shapiro-Wilk test, and homogeneity, using the Barlett test. Subsequently, the mean values were submitted to analysis of variance (ANOVA) using the F-test (P ≤ 0.05) and, when statistically significant, the mean values were compared by the Tukey test (P ≤ 0.05). The number of damaged mango fruits was subjected to a two-way analysis of variance with PROC GLM (SAS Institute 2011SAS INSTITUTE INC. 2011. Statistical analysis system: getting started with the SAS learning. SAS Institute, Cary, NC.). The differences between the treatments within each harvest and year were determined by the least squares means (PDIFF option in PROC GLM) using Tukey’s adjustment at 5% significance (SAS Institute 2011SAS INSTITUTE INC. 2011. Statistical analysis system: getting started with the SAS learning. SAS Institute, Cary, NC.).

RESULTS

Monitoring of C. capitata adults

In 2016/2017 experiment – Area 1, compared with the control condition, the two toxic baits tested suppressed C. capitata adults (Fig. 1). At 35 DBH, a high number of adults were captured in all areas, showing the high population of the insects in each area. The subsequent evaluations verified that there was a significant reduction in the number of insects captured in all three treatments; however, compared with the control, the Gelsura® and Success® 0.02 CB toxic baits reduced the number of medflies captured in all evaluations (F= 23.51; df = 2, 121; P < 0.0001). When comparing only the toxic bait formulations, the alpha-cypermethrin-based Gelsura® showed a greater reduction in the number of insects captured than the spinosad-based Success® 0.02 CB in all evaluations, reaching a 96% and 48% infestation reduction at harvest (0 DBH), respectively (Fig. 1).

Figure 1
Average number of flies per trap per day (average ± standard error) showing the Ceratitis capitata infestation reduction over six weeks of evaluations in mango crop areas during the period the 2016/2017 (experiment 1 (area 1)., Petrolina, PE, Brazil, 2017. The “days” lines followed by the same letter do not significantly differ as determined by the Tukey test (P > 0.05).

The experiment (area) 2 (2017/2018 harvest), the plots where toxic baits were applied also showed suppressed C. capitata populations during the period from 35 DBH to 0 DBH; the Gelsura® and Success® 0.02 CB toxic baits reduced the infestation level below the infestation level of the control treatment (Fig. 2). In this area, there was no difference (F= 38.12; df= 2, 121; P < 0.5644) between the toxic baits with regard to the number of medfly adults captured, although the Gelsura® toxic bait provided an infestation reduction of 79% at 0 DBH, while the infestation reduction was only 64% for the Success® 0.02 CB toxic bait (Fig. 2). The experiment (area) 3 (2017/2018 harvest), all plots containing toxic bait applications suppressed the medfly population until 0 DBH (Fig. 3). The plots where the Gelsura® and Success® 0.02 CB toxic baits were applied had reduced C. capitata populations, with flies per trap per day (FTD) values of 5.28 and 10.0, respectively, and the C. capitata population in these plots were lower than that in the control plot, with 35.9 FTD at 0 DBH (F= 41.76; df= 2, 121; P < 0.0001) (Fig. 3).

Figure 2
Average number of flies per trap per day (average ± standard error) showing the Ceratitis capitata infestation reduction over six weeks of evaluations in mango crop areas, during the period the 2017/2018 (experiment 2 (area 2). Petrolina, PE, Brazil, 2018. The “days” lines followed by the same letter do not significantly differ as determined by the Tukey test (P > 0.05).

Figure 3
Average number of flies per trap per day (average ± standard error) showing the Ceratitis capitata infestation reduction over six weeks of evaluations in mango crop areas, during the period the 2017/2018 (experiment 3 (area 3)). Casa Grande, BA, Brazil, 2018. The “days” lines followed by the same letter do not significantly differ as determined by the Tukey test (P > 0.05).

Injuries in mango fruits

In 2016/2017 experiment – Area 1, there was a significant reduction in the cumulative damage of fallen mango fruits (F= 16.11; df= 2, 44; P < 0.0001) in the plots where the Gelsura® (60% fallen mango fruits) and Success® 0.02 CB toxic baits were sprayed (67% fallen mango fruits) compared with the control plot (98% fallen mango fruits) (Fig. 4). For damaged fruits, the damage to the fruits in the experimental plots sprayed with the Gelsura® toxic bait (0.7% of fruits were punctured) and Success® 0.02 CB (3% of fruits were punctured) toxic bait was significantly lower (F= 22.60; df= 2, 44; P < 0.0011) than the damage to the fruits in the control plot (13.0% of fruits were punctured). In the experiment (area) 2 (2017/2018), the highest amount of mango fruits recovered in the soil with punctures by C. capitata was observed in the control plot (28% fallen mango fruits), and the number of punctures observed was significantly higher (F= 15.11; df= 2, 44; P < 0.0001) in the control plot than in the plots treated with the toxic baits Gelsura® and Success® 0.02 CB (13% fallen mango fruits) (Fig. 4). In experiment 2, there were no punctures observed on the evaluated mangoes recovered from trees in all experimental plots. The experiment (area) 3 (2017/2018), the number fallen fruits observed in the plots treated with the Gelsura® (48% fallen mango fruits containing punctures) and Success® 0.02 CB toxic baits (52% fallen mango fruits) was statistically (F= 10.14; df= 2, 44; P < 0.0001) lower than that observed in the control plots (68% fallen mango fruits) (Fig. 4). Regarding the percentage of punctured fruits on trees, no significant difference was observed (F= 2.10; df= 2, 44; P = 0.1420) was observed among the Gelsura® toxic bait (0.0% of fruits punctured), Success® 0.02 CB toxic bait (0.33% of fruits punctured) and the control treatments (1.0% of fruits punctured).

Figure 4
Percentage of mango fruit damage caused by Ceratitis capitata in each treated plot over three weeks of evaluations in mango crop areas, during the period 2016/2017 and 2017/2018. The “area 1, 2 or 3” columns followed by the same letter do not significantly differ as determined by the Tukey test (P > 0.05).

DISCUSSION

The use of toxic baits started when C. capitata infestation was high on traps (between 74 and 102.7 FTD), approximately 70 days after flower anthesis or 40 DBH (Rodrigues et al. 2013RODRIGUES, JC, SOUZA PJOP & LIMA RT. 2013. Estimativa de temperaturas basais e exigência térmica em mangueiras no Nordeste do Estado do Pará. Rev Bras Frutic 35: 143-150.). However, even in this physiological phase, there were large C. capitata individuals trapped on the traps (about 5 to 8 fruit flies), probably due the presence of a large amount of aborted fruits in response to the high temperature, which is characteristic of this region (Carvalho et al. 2004). It was also observed that although the toxic baits reduced the C. capitata population in all tested areas, the population was still above 1.0 FTD, which is the accepted level for export (Navarro-Llopis et al. 2013NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482.).

The high population during the initial development of fruits and the incapability of toxic baits to control 100% of the insects require special attention by growers and highlights the need for the adoption of complementary strategies to bring the fruit fly population below accepted levels, such as the collection and destruction of aborted fruits and starting toxic bait applications at least 40 days before harvest.

The use of toxic baits is an essential technique to suppress C. capitata adults as an alternative to spraying conventional insecticides (Navarro-Llopis et al. 2013NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482., Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... ). The reduction in the adult population recorded in areas treated with a spray solutions of the toxic bait based on alpha-cypermethrin (3.0 L.ha^-1) was greater than those treated with the spinosad-based toxic bait (4.0 L,ha^-1). This finding is related to alpha-cypermethrin, which is a polymer matrix containing a series of food attractants (Ruiz et al. 2008RUIZ L, FLORES S, CANCINO J, ARREDONDO J, VALLE J, DIAZ-FLEISCHER F & WILLIAMS T. 2008. Lethal and sublethal effects of spinosad-based GF-120 bait on the Tephritid parasitoid Diachasmimorpha longicaudata (Hymenoptera: Braconidae). Biol Control 44: 296-304.), and the parapheromone trimedlure, which results in marked attraction and capture of C. capitata males. This bait consequently reduces the population in the traps baited with the parapheromone Iscalure® TML-plug, resulting in a more reduction in infestation than that observed with the Success® 0.02 CB toxic bait. Promising results were shown by a toxic bait based on alpha-cypermethrin in Europe for the suppression of C. capitata and Bactrocera oleae in Clonorchis sinensis and Olea europea crops, respectively (Ruiz et al. 2008RUIZ L, FLORES S, CANCINO J, ARREDONDO J, VALLE J, DIAZ-FLEISCHER F & WILLIAMS T. 2008. Lethal and sublethal effects of spinosad-based GF-120 bait on the Tephritid parasitoid Diachasmimorpha longicaudata (Hymenoptera: Braconidae). Biol Control 44: 296-304.) and for the control of C. capitata populations in grape crops in Brazil (Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... ).

In mango orchards, the use of five sequential applications of toxic bait based on alpha-cypermethrin at 7-days intervals starting 35 days prior to harvesting reduced the infestation of medfly adults to levels that were lower than or equal to the areas treated with the spinosad toxic bait and the untreated areas (control). One variable to be evaluated in future studies is the FTD index at higher intervals between applications, since both of these baits can last for a long period of time in the São Francisco River Valley, where precipitation is low, depending on the season (Lopes et al. 2017LOPES I, GUIMARÃES MJH, MELO JMM & RAMOS CMC. 2017. Balanço hídrico em função de regimes pluviométricos na região de Petrolina-PE. Irriga 22: 443-457., Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... ).

In the São Francisco River Valley, fruit growers often use chemical management with insecticide sprays for the total area or toxic bait formulations. In this way, the ready-to-use toxic baits based on alpha-cypermethrin and spinosad can reduce C. capitata infestations and the percentage of damaged fruits. Both toxic baits can be used in an insecticide rotation with etofenprox (Safety®) because they are effective and authorized for pest management in mango crops (Morelli et al. 2012MORELLI R, PARANHOS BAJ & COSTA MLZ. 2012. Eficiência de Etofenproxi e Acetamiprido no controle de mosca-do-mediterrâneo Ceratitis capitata (Diptera: Tephritidae) em pomar de manga. Bioassay 7: 1-6.). However, due to restrictions on the use of chemical products by the consumer market demand for products without contaminants, the use of toxic baits such as spinosad and alpha-cypermethrin allows for the efficient management of C. capitata without contaminating mango fruits or the environment with insecticide residues (Vargas et al. 2013VARGAS RI, STARK JD, BANKS J, LEBLANC L, MANOUKIS N & PINERO JC. 2013. Spatial dynamics of two oriental fruit fly (Diptera: Tephritidae) parasitoids, Fopius arisanus (Sonan) and Diachasmimorpha longicaudata (Ashmead) (Hymenoptera: Braconidae), in a guava orchard in Hawaii. Environ Entomol 42: 888-901., Botton et al. 2016BOTTON M, ARIOLI CJ, MACHOTA R, NUNES MZ & ROSA JM. 2016. Moscas-das-frutas na fruticultura de clima temperado: situação atual e perspectivas de controle através do emprego de novas formulações de iscas tóxicas e da captura massal. Agropecuária Catarinense 29: 103-108., Baronio et al. 2018BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
https://doi.org/10.1590/0001-37652018201... ).

Thus, the ‘attract & kill’ technology by using toxic baits containing alpha-cypermethrin is a management tool for the suppression of the C. capitata population in mango orchards and can be an alternative to the rotation of active ingredients such as spinosad, which is the only ready-to-use toxic bait registered for mango crops, in addition to etofenprox and acetamiprid, which are used as conventional insecticides for medfly in the São Francisco River Valley.

ACKNOWLEDGMENTS

Thanks to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq). To Laboratory of Entomology at Embrapa Semiárido forthe support provided to this research work.

REFERENCES

BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
» https://doi.org/10.1590/0001-3765201820180707
BOTTON M, ARIOLI CJ, MACHOTA R, NUNES MZ & ROSA JM. 2016. Moscas-das-frutas na fruticultura de clima temperado: situação atual e perspectivas de controle através do emprego de novas formulações de iscas tóxicas e da captura massal. Agropecuária Catarinense 29: 103-108.
CARVALHO CRL ROSSETTO CJ, MANTOVANI DMB, MORGANO MA, CASTRO JV & BORTOLETTO N. 2004. Avaliação de cultivares de mangueira selecionadas pelo Instituto Agronômico de Campinas comparadas a outras de importância comercial. Rev Bras Frutic 26: 264-271.
COOK DC & FRASER RW. 2015. Erradication versus control of Mediterranean fruit fly in Western Australia. Agr Forest Entomol 17: 173-180.
FERREIRA MDP, LIRIO VS & MENDONÇA TG. 2010. Análise do perfil e grau de incidência de barreiras não-tarifárias sobre as exportações brasileiras de frutas selecionadas. Revista Econômica do Nordeste 41: 683-698.
HÄRTER WR, BOTTON M, NAVA DE, GRUTZMACHER AD, GONÇALVES RS, MACHOTA JR R, BERNARDI D & ZANARDI OZ. 2015. Toxicities and residual effects of toxic baits containing Spinosad or Malathion to control the adult Anastrepha fraterculus (Diptera: Tephritidae). Fla Entomol 98: 202-208.
JANG EB, KHRIMIAN A, HOLLER TC, CASANA-GINER V, LUX S & CARVALHO LA. 2005. Field response of Mediterranean fruit fly (Diptera: Tephritidae) to Ceralure B1: evaluations of enantiomeric B1 ratios on fly captures. J Econ Entomol 98: 1139-1143.
LOPES I, GUIMARÃES MJH, MELO JMM & RAMOS CMC. 2017. Balanço hídrico em função de regimes pluviométricos na região de Petrolina-PE. Irriga 22: 443-457.
MANGAN RL & MORENO AMT. 2009. Honeybee foraging preferences, effects of sugars and fruit fly toxic bait components. J Econ Entomol 102: 1472-1481.
MCQUATE GT & LIQUIDO NJ. 2017. Host Plants of Invasive Tephritid Fruit Fly Species of Economic Importance. Int J Plant Biol Res 5: 1072.
MALACRIDA AR, MARINONI F, TORTI C, GOMULSKI LM, SEBASTIANI F, BONVICINI C, GASPERI G & GUGLIELMINO CR. 1998. Genetic aspects of the worldwide colonization process of Ceratitis capitata. J Hered 89: 501-507.
MORELLI R, PARANHOS BAJ & COSTA MLZ. 2012. Eficiência de Etofenproxi e Acetamiprido no controle de mosca-do-mediterrâneo Ceratitis capitata (Diptera: Tephritidae) em pomar de manga. Bioassay 7: 1-6.
NAVARRO-LLOPIS V, ALFARO C, PRIMO J & VACAS S. 2011. Response of two Tephritid species, Bactrocera oleae and Ceratitis capitata to different emission levels of pheromone and parapheromone. Crop Prot 30: 913-918.
NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482.
NAVARRO-LLOPIS V, PRIMO V & VACAS S. 2015. Bait station devices can improve mass trapping performance for the control of the Mediterranean fruit fly. Pest Manag Sci 71: 923-927.
NELDER JA & WEDDERBURN RWM. 1972. Generalized linear models. J R Stat Soc Ser A 135: 370-384.
RAGA A & SATO ME. 2011. Toxicity of neonicotinoids to Ceratitis capitata and Anastrepha fraterculus (Diptera: Tephritidae). J Plant Prot Res 51: 413-419.
REYNOLDS OL, OSBORNE T, CRISP P & BARCHIA IM. 2016. Specialized pheromone and lure application technology as an alternative male annihilation technique to manage Bactrocera tryoni (Diptera: Tephritidae). J Econ Entomol 109: 1254-1260.
RODRIGUES, JC, SOUZA PJOP & LIMA RT. 2013. Estimativa de temperaturas basais e exigência térmica em mangueiras no Nordeste do Estado do Pará. Rev Bras Frutic 35: 143-150.
RUIZ L, FLORES S, CANCINO J, ARREDONDO J, VALLE J, DIAZ-FLEISCHER F & WILLIAMS T. 2008. Lethal and sublethal effects of spinosad-based GF-120 bait on the Tephritid parasitoid Diachasmimorpha longicaudata (Hymenoptera: Braconidae). Biol Control 44: 296-304.
SAS INSTITUTE INC. 2011. Statistical analysis system: getting started with the SAS learning. SAS Institute, Cary, NC.
SILVA AC, SOUZA AP & LEONEL S. 2014. Growth and flowering of five mango cultivar under subtropics conditions of Brazil. Amer J Plant Sci 5: 393-402.
STARK JD, VARGAS R & MILLER N. 2004. Toxicity of spinosad in protein bait to three economically important tephritid fruit fly species (Diptera: Tephritidae) and their parasitoids (Hymenoptera: Braconidae). J Econ Entomol 97: 911-915.
VARGAS RI, STARK JD, BANKS J, LEBLANC L, MANOUKIS N & PINERO JC. 2013. Spatial dynamics of two oriental fruit fly (Diptera: Tephritidae) parasitoids, Fopius arisanus (Sonan) and Diachasmimorpha longicaudata (Ashmead) (Hymenoptera: Braconidae), in a guava orchard in Hawaii. Environ Entomol 42: 888-901.
VARGAS RI, SOUDER SK, RENDON P & MACKEY B. 2018. Suppression of Mediterranean fruit fly (Diptera: Tephritidae) with trimedlure and biolure dispensers in Coffea arabica (Gentianales: Rubiaceae) in Hawaii. J Econ Entomol 111: 293-297.

Publication Dates

Publication in this collection
04 Dec 2023
Date of issue
2023

History

Received
09 Sept 2019
Accepted
19 Nov 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] BARONIO CA, BERNARDI D, PARANHOS BAJ, GARCIA FRM & BOTTON M. 2018. Population suppression of Mediterranean fruit fly Ceratitis capitata (Wiedemann) on table grapes using toxic baits. An Acad Bras Cienc 90: 3963-3973. https://doi.org/10.1590/0001-3765201820180707.
» https://doi.org/10.1590/0001-3765201820180707

[2] BOTTON M, ARIOLI CJ, MACHOTA R, NUNES MZ & ROSA JM. 2016. Moscas-das-frutas na fruticultura de clima temperado: situação atual e perspectivas de controle através do emprego de novas formulações de iscas tóxicas e da captura massal. Agropecuária Catarinense 29: 103-108.

[3] CARVALHO CRL ROSSETTO CJ, MANTOVANI DMB, MORGANO MA, CASTRO JV & BORTOLETTO N. 2004. Avaliação de cultivares de mangueira selecionadas pelo Instituto Agronômico de Campinas comparadas a outras de importância comercial. Rev Bras Frutic 26: 264-271.

[4] COOK DC & FRASER RW. 2015. Erradication versus control of Mediterranean fruit fly in Western Australia. Agr Forest Entomol 17: 173-180.

[5] FERREIRA MDP, LIRIO VS & MENDONÇA TG. 2010. Análise do perfil e grau de incidência de barreiras não-tarifárias sobre as exportações brasileiras de frutas selecionadas. Revista Econômica do Nordeste 41: 683-698.

[6] HÄRTER WR, BOTTON M, NAVA DE, GRUTZMACHER AD, GONÇALVES RS, MACHOTA JR R, BERNARDI D & ZANARDI OZ. 2015. Toxicities and residual effects of toxic baits containing Spinosad or Malathion to control the adult Anastrepha fraterculus (Diptera: Tephritidae). Fla Entomol 98: 202-208.

[7] JANG EB, KHRIMIAN A, HOLLER TC, CASANA-GINER V, LUX S & CARVALHO LA. 2005. Field response of Mediterranean fruit fly (Diptera: Tephritidae) to Ceralure B1: evaluations of enantiomeric B1 ratios on fly captures. J Econ Entomol 98: 1139-1143.

[8] LOPES I, GUIMARÃES MJH, MELO JMM & RAMOS CMC. 2017. Balanço hídrico em função de regimes pluviométricos na região de Petrolina-PE. Irriga 22: 443-457.

[9] MANGAN RL & MORENO AMT. 2009. Honeybee foraging preferences, effects of sugars and fruit fly toxic bait components. J Econ Entomol 102: 1472-1481.

[10] MCQUATE GT & LIQUIDO NJ. 2017. Host Plants of Invasive Tephritid Fruit Fly Species of Economic Importance. Int J Plant Biol Res 5: 1072.

[11] MALACRIDA AR, MARINONI F, TORTI C, GOMULSKI LM, SEBASTIANI F, BONVICINI C, GASPERI G & GUGLIELMINO CR. 1998. Genetic aspects of the worldwide colonization process of Ceratitis capitata. J Hered 89: 501-507.

[12] MORELLI R, PARANHOS BAJ & COSTA MLZ. 2012. Eficiência de Etofenproxi e Acetamiprido no controle de mosca-do-mediterrâneo Ceratitis capitata (Diptera: Tephritidae) em pomar de manga. Bioassay 7: 1-6.

[13] NAVARRO-LLOPIS V, ALFARO C, PRIMO J & VACAS S. 2011. Response of two Tephritid species, Bactrocera oleae and Ceratitis capitata to different emission levels of pheromone and parapheromone. Crop Prot 30: 913-918.

[14] NAVARRO-LLOPIS V, PRIMO J & VACAS S. 2013. Efficacy of attract-and-kill devices for the control of Ceratitis capitata. Pest Manag Sci 29: 478-482.

[15] NAVARRO-LLOPIS V, PRIMO V & VACAS S. 2015. Bait station devices can improve mass trapping performance for the control of the Mediterranean fruit fly. Pest Manag Sci 71: 923-927.

[16] NELDER JA & WEDDERBURN RWM. 1972. Generalized linear models. J R Stat Soc Ser A 135: 370-384.

[17] RAGA A & SATO ME. 2011. Toxicity of neonicotinoids to Ceratitis capitata and Anastrepha fraterculus (Diptera: Tephritidae). J Plant Prot Res 51: 413-419.

[18] REYNOLDS OL, OSBORNE T, CRISP P & BARCHIA IM. 2016. Specialized pheromone and lure application technology as an alternative male annihilation technique to manage Bactrocera tryoni (Diptera: Tephritidae). J Econ Entomol 109: 1254-1260.

[19] RODRIGUES, JC, SOUZA PJOP & LIMA RT. 2013. Estimativa de temperaturas basais e exigência térmica em mangueiras no Nordeste do Estado do Pará. Rev Bras Frutic 35: 143-150.

[20] RUIZ L, FLORES S, CANCINO J, ARREDONDO J, VALLE J, DIAZ-FLEISCHER F & WILLIAMS T. 2008. Lethal and sublethal effects of spinosad-based GF-120 bait on the Tephritid parasitoid Diachasmimorpha longicaudata (Hymenoptera: Braconidae). Biol Control 44: 296-304.

[21] SAS INSTITUTE INC. 2011. Statistical analysis system: getting started with the SAS learning. SAS Institute, Cary, NC.

[22] SILVA AC, SOUZA AP & LEONEL S. 2014. Growth and flowering of five mango cultivar under subtropics conditions of Brazil. Amer J Plant Sci 5: 393-402.

[23] STARK JD, VARGAS R & MILLER N. 2004. Toxicity of spinosad in protein bait to three economically important tephritid fruit fly species (Diptera: Tephritidae) and their parasitoids (Hymenoptera: Braconidae). J Econ Entomol 97: 911-915.

[24] VARGAS RI, STARK JD, BANKS J, LEBLANC L, MANOUKIS N & PINERO JC. 2013. Spatial dynamics of two oriental fruit fly (Diptera: Tephritidae) parasitoids, Fopius arisanus (Sonan) and Diachasmimorpha longicaudata (Ashmead) (Hymenoptera: Braconidae), in a guava orchard in Hawaii. Environ Entomol 42: 888-901.

[25] VARGAS RI, SOUDER SK, RENDON P & MACKEY B. 2018. Suppression of Mediterranean fruit fly (Diptera: Tephritidae) with trimedlure and biolure dispensers in Coffea arabica (Gentianales: Rubiaceae) in Hawaii. J Econ Entomol 111: 293-297.

Brasil

Brasil

The use of toxic baits for the suppression of Mediterranean fruit fly in mango orchards

Abstract

INTRODUCTION

MATERIALS AND METHODS

Treatments

Field Experiments

Monitoring of C. capitata adults

Evaluation to injuries in mango fruits

Statistical analysis

RESULTS

Monitoring of C. capitata adults

Injuries in mango fruits

DISCUSSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History