Effect of <i>Habrobracon hebetor</i> (Hymenoptera: Braconidae) Release on Moth Infestation in Stored Tobacco

Pezzini, Cleder; Zilch, Kássia Cristina Freire; Jahnke, Simone Mundstock; Köhler, Andreas

doi:10.1590/1678-4324-2023220278

Abstract

During the storage period of dry tobacco and its derivatives, insect pests such as species of Ephestia Guenée (Lepidoptera: Pyralidae), popularly known as moths, cause damage to the product, being controlled mainly with physical practices and synthetic chemicals, although with limitations on their use and results. Some biological control agents, such as the parasitoid Habrobracon hebetor (Say) (Hymenoptera: Braconidae), have the potential to control these pests. This study aimed to evaluate the effect of H. hebetor release in tobacco farms and industrial warehouses, on the infestation of Ephestia spp. adults. Parasitoids were released in tobacco farmers and tobacco industry warehouses between 2016-2018, comprising two years/crop seasons. Each release consisted of 1,000 parasitoids (four times) in tobacco farmers warehouses (70 m²) and 30,000 (five times) in tobacco industry warehouses (8,000 m²). Pheromone-baited sticky traps were used to weekly monitor the average number of adults of Ephestia spp. in warehouses with (WP) and without parasitoid release (NP). The average number of adults of Ephestia spp. captured in the traps in WP environments at farmers and industry level was significantly lower than the average captured in NP from the third and fifth weeks. In the following weeks, the averages of Ephestia spp. were always significantly lower in the WP environments until the end of monitoring. Therefore, the use of H. hebetor for moth control should be considered as part of a biological control program in stored tobacco environments.

Keywords:
integrated pest management; post-harvest; parasitoid; Ephestia spp.; biological control.

HIGHLIGHTS

• The H. hebetor parasitoid is effective to control the population of Ephestia spp.

• The potential of H. hebetor in stored tobacco is recorded for the first time in Brazil.

• H. hebetor can be part of an integrated pest management program in stored tobacco.

INTRODUCTION

Brazil is currently the largest exporter country of leaf tobacco (Nicotiana tabacum L.) and the second largest producing, only behind China [¹1 Kist BB, Carvalho C de, Fardi I, Garcia P, Beling RR. Anuário brasileiro do tabaco 2020 [Brazilian tobacco yearbook 2020]. Santa Cruz do Sul: Editora Gazeta Santa Cruz; 2020. 132 p.]. The crop has great economic importance by its high commercial value and capacity to employ a large number of people, both in cultivation and in industrialization [²2 Kist BB, Carvalho C de, Beling RR, Treichel M, Garcia P. Anuário brasileiro do tabaco 2019 [Brazilian tobacco yearbook 2019]. Santa Cruz do Sul: Editora Gazeta Santa Cruz; 2019. 132 p.]. It is mainly planted in South Brazil region and Rio Grande do Sul state has the largest cultivation area, with 127,000 hectares [¹1 Kist BB, Carvalho C de, Fardi I, Garcia P, Beling RR. Anuário brasileiro do tabaco 2020 [Brazilian tobacco yearbook 2020]. Santa Cruz do Sul: Editora Gazeta Santa Cruz; 2020. 132 p.].

From seedling production to the post-harvest of tobacco, a set of pathogens and insects can attack the crop, causing losses in production, yield, and quality [³3 Edde PA. Principal insects affecting tobacco plants in the field. Beiträge zur Tabakforschung International / Contributions to Tobacco Research. 2018;28(3):117-65.]. During the tobacco storage period, two groups of insects cause significant damage: the cigarette beetle Lasioderma serricorne Fabricius (Coleoptera: Ptinidae); and the moths Ephestia elutella (Hübner) (tobacco moth), Ephestia kuehniella (Zeller) (flour moth), and Ephestia cautella (Walker) (cocoa moth) (Lepidoptera: Pyralidae) [⁴4 Krsteska V. Ephestia elutella Hüb. on tobacco. Тутун / Tobacco. 2014;64(1-6):70-7.]. Moth species occur in set, however, in different proportions depending on the region, being difficult for identification, since they are cryptic species [⁵5 Slone JD, Burrack HJ. Integrated pest management practices reduce insecticide applications, preserve beneficial insects, and decrease pesticide residues in flue-cured tobacco production. J Econ Entom. 2016;109(6):2397-404.].

In tobacco crop, it is estimated that approximately 3% of production is lost to the presence of insects in storage [⁶6 Li Y, Yu X. Occurrence and damage of main tobacco pests and their control. Tobacco science & technology. 1993;4:29-31.]. The methods currently used to control these pests are generally based on the use of chemical insecticides that are highly toxic to humans and the environment [⁷7 Sabbour M. Integrated pest control of stored product insect pests. Sarbruque: Lambert Academic Publishin; 2020. 104 p.]. In Brazil, only phosphine (aluminum or magnesium phosphide) is authorized to be used as a phytosanitary product in the control of insects in warehouses with stored tobacco [⁸8 Agrofit. Sistema de Agrotóxicos Fitossanitários. Consulta de praga/doença [Phytosanitary Pesticides System. Pest/disease research]. [Internet]. [updated 2022; cited 2022 Feb 9]. Available from: http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
http://agrofit.agricultura.gov.br/agrofi... ]. As a result, the need to develop new technologies to be adopted as management strategies increases.

Augmentative biological control is a tool, in which natural enemies, such as parasitoids, are used to decrease populations of organisms that are considered pests in agricultural systems [⁹9 Schöller M, Prozell S, Suma P, Russo A. Biological control of stored-product insects. In: Athanassiou CG, Arthur FH, editors. Recent advances in stores product protection. Berlin: Springer; 2018. p. 183-210.]. Natural enemies of stored product pests can offer advantages over traditional chemical treatments. Parasitoids, for example, continue to reproduce as long as their hosts are available and can be released at specific points and actively spread to find the target in hidden locations [¹⁰10 Soares MA, Zanuncio JC, Leite GLD, Reis TC, Silva MA. Controle biológico de pragas em armazenamento: uma alternativa para reduzir o uso de agrotóxicos no Brasil? [Biological control of pests in storage: is an alternative to reduce the use of pesticides in Brazil?]. Unimontes Científica. 2009;11(1-2):52-9.]. This can be especially important for eliminating focal points of moth infestation that often thrive in dust accumulated in nooks and crannies of food storage environments [¹¹11 Castañé C, Riudavets J, Lucas E. Parasitism of single or combined pyralid populations by Venturia canescens and Habrobracon hebetor in laboratory and storeroom conditions. J Pest Sci. 2018;91(1):1-8.].

The larval ectoparasitoid Habrobracon hebetor (Say) (Hymenoptera: Braconidae) stands out as a potential biocontrol agent for stored pests [¹²12 Mbata GN, Warsi S. Habrobracon hebetor and Pteromalus cerealellae as tools in post-harvest integrated pest management. Insects. 2019;10(85):1-12.]. This species has been promising in laboratory experiments to control various pest moths present in different stored product environments [¹³13 Ghimire MN, Phillips TW. Oviposition and reproductive performance of Habrobracon hebetor (Hymenoptera: Braconidae) on six different pyralid host species. Ann Entomol Soc Am. 2014;107(4):809-17., ¹⁴14 Ou HD, Atlihan R, Wang XQ, Li HX, Yu XF, Jin X, et al. Host deprivation effects on population performance and paralysis rates of Habrobracon hebetor (Hymenoptera: Braconidae). Pest Manag Sci. 2021;77(4):1851-63.].

Its control ability has already been evaluated on many moth species like E. elutella, E. kuehniella, E. cautella, Plodia interpunctella (Hübner), Corcyra cephalonica (Stainton) (Lepidoptera: Pyralidae) and Sitotroga cerealella (Olivier) (Lepidoptera: Gelechiidae) in different products and storage environments, either alone or in combination with other parasitoids [¹¹11 Castañé C, Riudavets J, Lucas E. Parasitism of single or combined pyralid populations by Venturia canescens and Habrobracon hebetor in laboratory and storeroom conditions. J Pest Sci. 2018;91(1):1-8., ¹⁵15 Belda C, Riudavets J. Natural enemies associated with lepidopteran pests in food and feed processing companies. J Stored Prod Res. 2013;53:54-60.]. Studies were conducted in the storage of bulk wheat [¹⁶16 Press JW, Cline LD, Flaherty BR. A comparison of two parasitoids, Bracon hebetor (Hymenoptera: Braconidae) and Venturia canescens (Hymenoptera: Ichneumonidae), and a predator Xylocoris flavipes (Hemiptera: Anthocoridae) in suppressing residual population of the almond moth, Ephestia cautella (Lepidoptera: Pyralidae). J Kans Entomol Soc. 1982;55(4):125-8., ¹⁷17 Adarkwah C, Schöller M. Biological control of Plodia interpunctella (Lepidoptera: Pyralidae) by single and double releases of two larval parasitoids in bulk stored wheat. J Stored Prod Res. 2012;51:1-5.], bulk peanuts [¹⁸18 Brower JH, Press JW. Interaction of Bracon hebetor (Hymenoptera: Braconidae) and Trichogramma pretiosum (Hymenoptera: Trichogrammatidae) in suppressing storedproduct moth populations in small inshell peanut storages. J Econ Entom. 1990;83(3):1096-101.], packaged cornmeal and rice [¹⁹19 Cline LD, Press JW, Flaherty BR. Preventing the spread of the almond moth (Lepidoptera: Pyralidae) from infested food debris to adjacent uninfested packages, using the parasitoid Bracon hebetor (Hymenoptera: Braconidae). J Econ Entom. 1984;77(2):331-3., ²⁰20 Adarkwah C, Ulrichs C, Schaarschmidt S, Badii BK, Addai IK, Obeng-Ofori D, et al. Potential of Hymenopteran larval and egg parasitoids to control stored product beetle and moth infestation in jute bags. Bull Entom Res. 2014;104(4):534-42.], bakeries and mills [²¹21 Prozel S, Schöller M. Five years of biological control of stored-product moths in Germany. In: Credland PF, Armitage DM, Bell CH, Cogan PM, Highley E, editors. Advances in stored product protection. Wallingford: CABI Publishing; 2003. p. 322-4.], and chocolate factories [²²22 Trematerra P, Oliviero A, Savoldelli S, Schöller M. Controlling infestation of a chocolate factory by Plodia interpunctella by combining mating disruption and the parasitoid Habrobracon hebetor. Insect Sci. 2016;24(3):503-510.]. The authors considered aspects such as parasitism rate, number of pest adults captured in the traps, number and frequency of releases and search capacity to determine the efficiency of the parasitoid.

In stored tobacco, H. hebetor was already recorded parasitizing larvae of Ephestia spp. Guenée (Lepidoptera: Pyralidae) [²³23 Parra JRP. Biological control in Brazil: An overview. Sci Agric. 2014;71(5):345-55.]. In the laboratory, it is known that H. hebetor parasites fifth instar larvae of E. kuehniella fed on a tobacco diet [²⁴24 Pezzini C, Jahnke SM, Köhler A. Influence of a diet containing tobacco on the biology of Ephestia kuehniella (Lepidoptera: Pyralidae) and its parasitoid Habrobracon hebetor (Hymenoptera: Braconidae). Eur J Entomol. 2020;117:190-8.], being attracted by the odors of different types of tobacco [²⁵25 Pezzini C, Rosa KP, Jahnke SM, Köhler A. Chemotaxis of Habrobracon hebetor (Say) (Hymenoptera: Braconidae) in response to larvae of Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) and host food substrate with tobacco. J Stored Prod Res. 2020;89:101680.]. The attractiveness of tobacco volatiles to H. hebetor females may be due to the fact that the parasitoid recognizes the odor as the substrate where it is most likely to find its host [²⁵25 Pezzini C, Rosa KP, Jahnke SM, Köhler A. Chemotaxis of Habrobracon hebetor (Say) (Hymenoptera: Braconidae) in response to larvae of Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) and host food substrate with tobacco. J Stored Prod Res. 2020;89:101680.]. However, there is lack of information on its ability to control target pests in biggest stored tobacco environments. Thus, this study aimed to evaluate the effect of H. hebetor release in tobacco farms and industrial warehouses, on the infestation of Ephestia spp. adults.

MATERIAL AND METHODS

Parasitoid and host rearing

Habrobracon hebetor and E. kuehniella were reared in the Entomology Laboratory at the Universidade de Santa Cruz do Sul (UNISC), in acclimatized rooms at a temperature of 28 ± 2°C, relative humidity (RH) of 50 ± 20% and 14-h photoperiod. Ephestia kuehniella was reared on an artificial diet consisting of wheat flour (97%) and yeast (3%). The parasitoid was supplied with E. kuehniella larvae of the last instar to parasitize.

Containers of different sizes were used for parasitoid releases: 10 cm high x 10 cm diameter, for releases in tobacco farmers (with 500 parasitoids); and, 12 cm high x 16 cm wide and long (with 2,000 parasitoids) for releases in the tobacco industry warehouses. Different container sizes were used thus, the number of parasitoids released in the environments was different depending on the volume of tobacco stored and the size of the building. The sex ratio was around 0.7 females. The parasitoids were released when they began to emerge in the containers, which occurred approximately 14 days after the larvae were exposed to the parasitism. The number and frequency of parasitoids released in each of the systems were defined after a pilot experiment in the previous crop season (2015/2016).

Release in the warehouses of tobacco farmers

Twenty-two Virginia tobacco farmers associated with a tobacco company and with a history of Ephestia spp. infestations, were selected in locations of large-scale tobacco production in the municipalities of Arroio do Tigre (29° 19′ 22″ S, 53° 4′ 35″ W), Novo Cabrais (29° 44′ 24″ S, 52° 57′ 42″ W), Paraiso do Sul (29° 39′ 50″ S, 53° 8′ 54″ W) and Sobradinho (29° 25′ 22″ S, 53° 1′ 57″ W), within a radius of 25 km in central region of Rio Grande do Sul State, Brazil. Sixteen warehouses were designated for the release of H. hebetor and six are used as controls, without parasitoid release. The average size of the warehouses was 70 m² with an average capacity of 5.3 tons of tobacco stored at the end of the crop season. Two crop seasons were evaluated (2016/2017 and 2017/2018). At each season, different warehouses were selected, without repetition.

In each warehouse, four occasions of H. hebetor releases were conducted during the crop season. The first release was managed when the first bales (approximately 700 kg of dry tobacco) were stored on the site and the others at two-to-three-week intervals. Each release consisted of two containers (1,000 parasitoids).

Inside the warehouse, the containers with parasitoids were opened and placed on tobacco stacks with (an average height of 1.8 meters) at two different points. The containers remained on the site until the next release when they were collected.

Ephestia spp. was monitored inside the warehouses using pheromone-baited sticky traps by Gachon^® [(Z, E)-9,12-tetradecadienyl acetate]. Monitoring started one week before the first release of H. hebetor and continued until the farmers started selling the tobacco to companies.

According to the manufacturer’s recommendations, one Gachon^® trap per every 300 m² should be used for monitoring the population [⁸8 Agrofit. Sistema de Agrotóxicos Fitossanitários. Consulta de praga/doença [Phytosanitary Pesticides System. Pest/disease research]. [Internet]. [updated 2022; cited 2022 Feb 9]. Available from: http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
http://agrofit.agricultura.gov.br/agrofi... ]. Therefore, one trap was used per week in each warehouse, which was always installed on Monday and remained exposed for 48 hours, being removed on Wednesday of that same week. The trap was installed on a wall at a height of two meters and the farmers were instructed to conduct the weekly change, with the trap being preserved in a closed package. In the experiment, only the population of Ephestia spp. was monitored. During this period, no insecticide treatment was carried out in any warehouse. In the first (2016/2017) and second crop season (2017/2018), the monitoring took place from 12/12/2016 to 03/22/2017 and from 12/11/2017 to 03/21/2018, respectively, totalizing 15 weeks per crop season.

The experimental design consisted of 16 warehouses (farmers), randomly selected for the release of H. hebetor (WP) and six warehouses in which parasitoids were not released, constituting the control (NP). Each warehouse was considered a weekly replica.

Release in warehouses in tobacco industry

The experiment was conducted in two Virginia tobacco warehouses (unprocessed product) located in the municipality of Santa Cruz do Sul (29º43'59" S, 52º24'52" W), Rio Grande do Sul State, Brazil. Each environment had an area of approximately 8,000 m² and the capacity to store 5.5 thousand tons of tobacco. One warehouse was used for the parasitoid releases and the other as control, without releases. The volume of tobacco that had been stored inside the warehouses during the crop seasons increased as tobacco was purchased (Figure 1).

The release and monitoring methodology applied was similar to that used for tobacco farmers. Five releases were conducted during each crop season; the first one occurred when the company started buying tobacco from farmers and the others at two-to-three-week intervals. Each release consisted of 15 containers (30,000 parasitoids).

Due to the circulation of forklifts inside the warehouse, the containers with adult parasitoids were opened and placed on the floor in a row close to a side wall, with a distance of eight meters between each container, remaining in place until the occasion of the next release, when they were collected.

Ephestia spp. adults were monitored weekly using 10 traps described in the previous topic in each warehouse at a height of two meters. In the warehouse where releases occurred, the traps were placed on the same wall where the release was conducted, with a distance of ten meters between each trap. The traps were exposed weekly for 48 hours. The monitoring of moths started a week before the first release of H. hebetor to verify initial infestation and continued until the moment that tobacco processing started. During the experiment no insecticide treatments were carried out in any warehouse. In the 2016/2017 and 2017/2018 crop seasons, monitoring occurred from 03/13/2017 to 07/05/2017 and from 03/19/2018 to 07/11/2018 respectively, totalizing17 weeks per crop season.

The experimental design had a warehouse in which parasitoid releases were made (WP) and another, as a control, without releases (NP). Each trap was considered a pseudo-replica with 10 weekly repetitions.

Figure 1
Average volume (± standard error) of tobacco stored/square meter/week, within the two warehouses over the weeks during the 2016-2017 and 2017-2018 crop seasons.

Data analysis

The average data were evaluated for normality by the Shapiro-Wilk test, homoscedasticity by the Hartley test, and the independence of residuals was evaluated by graphical analysis. The average number of Ephestia spp. adults captured by a trap in the warehouses with and without H. hebetor release was compared using the t test. In order to relate the volume of tobacco stored in the industry with the average number of insects captured over the weeks, Pearson's correlation coefficient followed by power-normal distribution was used. The analysis was conducted using the Bioestat 5.0^® software at a significance level of 5% [²⁶26 Ayres M, Ayres Júnior M, Ayres DL, Santos AS dos. BioEstat 5.0 aplicações estatísticas na área das ciências biológicas e médicas [BioEstat 5.0 statistical applications in the biological and medical sciences]. Belém: Sociedade Civil Mamirauá; 2007. 364 p.].

RESULTS

The average number of adults of Ephestia spp. captured in the traps in the warehouses with the release of H. hebetor at farmers was significantly lower (19.18±5.27) than that of sites without release (41.50±11.62) from the third week (t = 2.3668; df = 20; p = 0.02), in the first crop season (Figure 2 a). In the second crop season, this difference occurred from the fifth week (WP = 13.50±2.29) and (NP = 25.66±3.84) (t = 2.1602; df = 20; p = 0.04) (Figure 2 b). In the subsequent weeks, in both crop seasons, the averages of Ephestia spp. were always significantly higher in warehouses without parasitoid release, and the values continued to increase until the end of monitoring (Figure 2 a b).

In the industry, the average number of Ephestia spp. trapped was significantly lower after the third week in the environment with the release of H. hebetor in the 2016/2017 crop season, (WP = 22.80±8.04) and (NP = 58.30±19.18) (t = 2.0218; df = 18; p = 0.05) (Figure 3 a). In the control warehouse, without parasitoid release, the moth population continued to increase and peaked in the seventh week (Figure 3 a). In the 2017/2018 crop season, the significant difference in the average number of Ephestia spp. trapped occurred from the fourth week of sampling, (WP = 48.60±13.55) and (NP = 82.50±13.98) (t = 2.0409; df = 18; p = 0.05) (Figure 3 b). The number of insects captured in the control warehouse peaked in the sixth week (Figure 3 b).

In the 2016/2017 crop season, a positive correlation was observed between the volume of tobacco stored in the industry and the average number of Ephestia spp. trapped every week in the environment without the release of H. hebetor (Figure 4), and 60% of this variation can be explained by the relationship between the volume of tobacco and the number of insects trapped. On the other hand, in the environment with parasitoid release, the correlation between these parameters was not observed (p > 0.05).

In the second season, no correlation was observed between the volume of tobacco stored and the average number of captured insects, both in warehouses with release of the parasitoid (y = 29.064x^-0.13, R² = 0.0065, p > 0.05) and those without (y = 267.28x^0.6457, R² = 0.293, p > 0.05).

Figure 2
Average number (± standard deviation) of Ephestia spp. adults trapped in warehouses of tobacco farmers with (16 warehouses) and without release (6 warehouses) of H. hebetor weekly (arrows indicate when the releases occurred = 1,000 parasitoids) in two crop seasons (a) 2016/2017 and (b) 2017/2018. Bars with an asterisk differ significantly between treatments by the t test (p≤0.05).

Figure 3
Average number (± standard deviation) of Ephestia spp. adults trapped in two warehouses in the industry with and without release of H. hebetor each week (arrows indicate when the releases occurred = 30,000 parasitoids) in the two crop seasons (a) 2016/2017 and (b) 2017/2018. Bars with an asterisk differ significantly between treatments by the t test (p≤0.05).

Figure 4
Correlation between the volume of tobacco stored and the average number of Ephestia spp. adults trapped every week in the warehouse in the industry without the release of H. hebetor during the 2016/2017 crop season.

DISCUSSION

The increase in the number of individuals caught in the traps of the warehouses of farmers over the weeks occurred since the volume of tobacco inside the storage environments gradually increased over the crop season, as the tobacco was harvested and cured. This increase in pest density is expected in storage environments since the volume of storage products increases, providing greater food availability for insects [²⁷27 Jian F, Jayas DS. The ecosystem approach to grain storage. Agric Res. 2012;1:148-56.]. In addition, with the greater amount of product available, chemical clues that attract more insects increase and insect reproduction occurs at the site [²⁸28 Anukiruthika T, Jian F, Jayas DS. Movement and behavioral response of stored product insects under stored grain environments - A review. J Stored Prod Res. 2021;90:101752.]. However, the increase in the number of Ephestia spp. individuals captured by pheromone traps were significantly lower in environments with the release of H. hebetor, showing that the parasitoid can slow the population growth of these moths even at the farmer level.

Similar to what was observed in farm warehouses, the increase in Ephestia spp. density associated with the increase in the volume of stored tobacco was recorded, which did not occur in warehouses with the release of parasitoids. Likewise, it happened possibly because the moth population was being controlled by the parasitoid and did not allow insect incidence to increase. In the following crop season, no correlation was observed between volume and Ephestia spp. trapped in the site without release, which may have occurred for the continuous flow of tobacco entering and leaving warehouses within the industry as the product was purchased and processed, without a static stock, different from the previous crop season. In addition, the volume of tobacco stored at the end of the season was lower compared to the first year.

During the storage period, there are several factors that can influence the population fluctuation of insects, such as tolerance to environmental conditions of temperature, humidity, light, quantity and quality of the food source, among others [²⁷27 Jian F, Jayas DS. The ecosystem approach to grain storage. Agric Res. 2012;1:148-56., ²⁹29 Nascimento JB. Fatores que afetam a liberação e a eficiência de parasitoides no controle biológico de insetos-praga [Factors affecting the release and efficiency of parasitoids in biological control of insect pests]. Enciclopédia Biosfera. 2011;7(13):550-70.]. However, these aspects were not evaluated in the present study. In addition, the origin of the tobacco that arrives at the industry does not have the same regularity from one crop to another and may come from different farmers or regions, with superior or inferior quality, which interferes with the infestation of insects in the warehouse.

The tobacco that entered the company was possibly already infested with Ephestia spp. from the farmers, since Deng and coauthors [³⁰30 Deng H, Ou HD, Jin X, Wang X, Li Y, Tian T, et al. Population dynamics and resource of Ephestia elutella (Hübner) in the tobacco warehouses in Guiyang of Guizhou Province. Plant Protection. 2018;44(6):172-6.] described the occurrence of moths on rural properties and we also recorded their presence in the evaluated warehouses. As H. hebetor infests moths in the larval phase [¹²12 Mbata GN, Warsi S. Habrobracon hebetor and Pteromalus cerealellae as tools in post-harvest integrated pest management. Insects. 2019;10(85):1-12.], moths that came from the farmers and were already in the pupal phase emerged and were trapped even after the parasitoids were released in the warehouse of industry. This explains the fact that the differences in the average density of moths per trap were only significant in the release environments from the third or fifth sampling occasion and the oscillation of individuals was registered according to the tobacco stock. Thus, we can infer that H. hebetor does not protect the infestation already present in the stored products, however, it will prevent their increase, reducing the next generation of moths [³¹31 Grieshop MJ, Flinn PW, Nechols JR. Biological control of Indianmeal moth (Lepidoptera: Pyralidae) on finished stored products using egg and larval parasitoids. J Econ Entom. 2006;99(4):1080-4.]. Therefore, in order for adequate suppression of Ephestia spp., releases should be made as early as possible so that the parasitoids have a chance to control moth populations before they reach the action level.

The effectiveness of H. hebetor has already been recorded, in the control of P. interpunctella in releases inside a chocolate factory for four years [²²22 Trematerra P, Oliviero A, Savoldelli S, Schöller M. Controlling infestation of a chocolate factory by Plodia interpunctella by combining mating disruption and the parasitoid Habrobracon hebetor. Insect Sci. 2016;24(3):503-510.]. The authors observed that the presence of H. hebetor reduced the number of P. interpunctella adults captured in the pheromone traps inside the factory. Adarkwah and Schöller [¹⁷17 Adarkwah C, Schöller M. Biological control of Plodia interpunctella (Lepidoptera: Pyralidae) by single and double releases of two larval parasitoids in bulk stored wheat. J Stored Prod Res. 2012;51:1-5.] evaluated the parasitism capacity of H. hebetor in P. interpunctella larvae in wheat stored in bulk and verified parasitism between 50 and 80 % of the larvae according to the density of parasitoids released. The combination of the release of a larval parasitoid species associated with an egg parasitoid, in this case, Trichogramma evanescens Westwood (Hymenoptera: Trichogrammatidae), improved the control of E. kuehniella and P. interpunctella in heated mills and bakeries [²¹21 Prozel S, Schöller M. Five years of biological control of stored-product moths in Germany. In: Credland PF, Armitage DM, Bell CH, Cogan PM, Highley E, editors. Advances in stored product protection. Wallingford: CABI Publishing; 2003. p. 322-4.]. Population suppression of P. interpunctella and E. cautella by H. hebetor was also recorded in peanut warehouses, being 60 and 90%, respectively [¹⁸18 Brower JH, Press JW. Interaction of Bracon hebetor (Hymenoptera: Braconidae) and Trichogramma pretiosum (Hymenoptera: Trichogrammatidae) in suppressing storedproduct moth populations in small inshell peanut storages. J Econ Entom. 1990;83(3):1096-101.].

In Brazil, the use of parasitoids in storage or processing facilities is still incipient. There is a record of the use of H. hebetor to control E. elutella in about 1,500 tobacco farmers in Brazil [²³23 Parra JRP. Biological control in Brazil: An overview. Sci Agric. 2014;71(5):345-55.]. However, the author only reports the use, without informing data regarding the number, time, release interval, dose, or control efficiency.

In our study, we observed that H. hebetor is able to be established in stored tobacco environments and act in the control of associated pests despite nicotine present in tobacco which is described as an insect repellent and is frequently used as an insecticide [³²32 Jacomini D, Temponi LG, Alves LFA, Silva EAA. da, Jorge TCM. Extrato de tabaco no controle do besouro cascudinho de aviário [Tobacco extract in the control of the mealworm beetle in aviaries]. Pesqui Agropecu Bras. 2016;51(5):680-3., ³³33 Ou HD, Jin X, Wang X, Liu J, Yang H, Yu X, et al. Control efficiency of Bracon hebetor say against Ephestia elutella (Hübner). Chinese Tobacco Science. 2019;40(5):44-51.]. This substance, like insecticides of the neonicotinoid group, acts as competitive modulator of nicotinic acetylcholine receptors and has a rapid effect that leads to hyperexcitation of the nervous system, which can be fatal for many insects [³⁴34 Kessler A, Baldwin IT. Plant responses to insect herbivory: the emerging molecular analysis. Annu Rev Plant Biol. 2002;53:299-328.]. The fact that the release of H. hebetor reduced the population of Ephestia spp., shows that this parasitoid species is adapted to the taco storage environment, which is toxic to other organisms. This adaptation has already been proven in a study that showed that H. hebetor presented a positive chemotactic response when responding to odors from different types of tobacco, especially to that of Virginia [²⁵25 Pezzini C, Rosa KP, Jahnke SM, Köhler A. Chemotaxis of Habrobracon hebetor (Say) (Hymenoptera: Braconidae) in response to larvae of Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) and host food substrate with tobacco. J Stored Prod Res. 2020;89:101680.]. In addition, H. hebetor is able to reproduce and develop in the host reared on a diet containing tobacco [²⁴24 Pezzini C, Jahnke SM, Köhler A. Influence of a diet containing tobacco on the biology of Ephestia kuehniella (Lepidoptera: Pyralidae) and its parasitoid Habrobracon hebetor (Hymenoptera: Braconidae). Eur J Entomol. 2020;117:190-8.]. Thus, although the offspring from released females has not been studied in the present study, there may have been offspring emergence and the second generation could reinforce the control of the target populations in warehouses.

Although H. hebetor is commercialized in some countries, only a few companies sell this parasitoid species, with examples of success only on a small scale [¹¹11 Castañé C, Riudavets J, Lucas E. Parasitism of single or combined pyralid populations by Venturia canescens and Habrobracon hebetor in laboratory and storeroom conditions. J Pest Sci. 2018;91(1):1-8.]. Despite the great potential of the species demonstrated in our study, one of the obstacles to the use of parasitoids in storage environments is that natural enemies can be considered as a type of contaminant present at the site [³⁵35 Cox PD, Wilkin DR. The potential use of biological control of pests in stored grain, Research Review 36. London: Home-Grown Cereals Authority; 1996. 53 p.]. However, some countries already have specific legislation on this subject, such as the United States, which allowed the increased release of beneficial insects in stored products. All genera of parasitoids and predators commonly known to control stored product pest insects were exempt by the Environmental Protection Agency (EPA) of a tolerance requirement on stored whole grains and packaged foods in warehouses, provided that insects do not become a food component [³⁶36 Flinn PW, Hagstrum DW. Augmentative releases of parasitoid wasps in stored wheat reduces insect fragments in flour. J Stored Prod Res. 2001;37(2):179-86.]. In addition, according to the same authors, it was demonstrated that the fragments of insect pests were reduced in grains treated with parasitoids. During tobacco processing specifically, the product passes through several sieves and air flows that remove small foreign particles that may be present [³⁷37 Collins WK, Hawks SN. Fundamentos da produção do tabaco de estufa [Principles of flue-cured tobacco production]. Santa Cruz do Sul: Edunisc; 2011. 82 p.]. This technique can also remove dead insects or fragments from the product being processed.

While releasing parasitoids into storage environments is in itself easy and does not require skilled workers, decisions about when and where to release them, are not. As with any other control technique, the warehouse situation must be analyzed and the anticipated storage or processing steps must be taken into account. In addition, an integrated post-harvest pest management system must comprise different strategies, such as hygiene, technological and biotechnological methods, physical, chemical and biological control. These techniques must be harmonized in order to grant protection of human health and the environment together with efficient pest control.

CONCLUSION

Our study presents the first records of the practical application of the use of H. hebetor in mass releases in tobacco storage, demonstrating the potential of the species for moth control. The number and frequency of releases of H. hebetor since the beginning of tobacco storage in farmers and tobacco industry warehouses, showed that the parasitoid reduced the number of captured adults of Ephestia spp. under these conditions.

Acknowledgments:

To Japan Tobacco International (JTI) company for the availability of tobacco farmers and warehouses to carry out the experiments.

Funding: This research was funded by National Council for Scientific and Technological Development (CNPq) with a doctor degree scholarship granted to the first author (140622/2017-9) and by Japan Tobacco International (JTI) for the financial support.

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Editor-in-Chief: Bill Jorge Costa

Associate Editor: Marcos Pileggi

Publication Dates

Publication in this collection
13 Feb 2023
Date of issue
2023

History

Received
14 Apr 2022
Accepted
13 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Funding: This research was funded by National Council for Scientific and Technological Development (CNPq) with a doctor degree scholarship granted to the first author (140622/2017-9) and by Japan Tobacco International (JTI) for the financial support.

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