Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-28T01:06:12.812Z Has data issue: false hasContentIssue false

Lateralised courtship behaviour and its impact on mating success in Ostrinia furnacalis (Lepidoptera: Crambidae)

Published online by Cambridge University Press:  19 April 2024

Sohail Abbas
Affiliation:
College of Plant Protection, Jilin Agricultural University, Changchun, Jilin, 130118 PR China
Aleena Alam
Affiliation:
College of Plant Protection, Jilin Agricultural University, Changchun, Jilin, 130118 PR China
Muneer Abbas
Affiliation:
Arid Zone Research Institute, Bhakkar, Punjab 30004 Pakistan
Arzlan Abbas
Affiliation:
College of Plant Protection, Jilin Agricultural University, Changchun, Jilin, 130118 PR China
Jamin Ali
Affiliation:
College of Plant Protection, Jilin Agricultural University, Changchun, Jilin, 130118 PR China
Menno Schilthuizen
Affiliation:
Naturalis Biodiversity Center, Darwinweg 2, 2333CR Leiden, The Netherlands Institute for Biology Leiden, Leiden University, Sylviusweg 72, 2333BE Leiden, The Netherlands
Donato Romano
Affiliation:
The BioRobotics Institute & Department of Excellence in Robotics and AI, Sant'Anna School of Advanced Studies, 56127 Pisa, Italy
Chen Ri Zhao*
Affiliation:
College of Plant Protection, Jilin Agricultural University, Changchun, Jilin, 130118 PR China
*
Corresponding author: Chen Ri Zhao; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Lateralisation is a well-established phenomenon observed in an increasing number of insect species. This study aims to obtain basic details on lateralisation in courtship and mating behaviour in Ostrinia furnacalis, the Asian corn borer. We conducted laboratory investigations to observe lateralisation in courtship and mating behaviours in adult O. furnacalis. Our goal was also to detect lateralised mating behaviour variations during sexual interactions and to elucidate how these variances might influence the mating success of males. Our findings reveal two distinct lateralised traits: male approaches from the right or left side of the female and the direction of male turning displays. Specifically, males approaching females from their right side predominantly exhibited left-biased 180° turning displays, while males approaching females from the left-side primarily displayed right-biased 180° turning displays. Notably, left-biased males, executing a 180° turn for end-to-end genital contact, initiated copulation with fewer attempts and began copulation earlier than their right-biased approaches with left-biased 180° turning displays. Furthermore, mating success was higher when males subsequently approached the right side of females during sexual encounters. Left-biased 180° turning males exhibited a higher number of successful mating interactions. These observations provide the first report on lateralisation in the reproductive behaviour of O. furnacalis under controlled laboratory conditions and hold promise for establishing reliable benchmarks for assessing and monitoring the quality of mass-produced individuals in pest control efforts.

Type
Research Paper
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Lateralisation, a phenomenon concerning the left-right asymmetrical organisation of brain functions and behaviours, has captivated the interest of neuroscientists (Güntürkün et al., Reference Güntürkün, Ströckens and Ocklenburg2020; Labache et al., Reference Labache, Ge, Yeo and Holmes2023). It represents an intriguing concept in neuroscience, enhancing brain efficiency by enabling the concurrent left-right processing of multiple information streams (David Fernandes and Niven, Reference David Fernandes and Niven2020; Desaunay et al., Reference Desaunay, Guillery, Moussaoui, Eustache, Bowler and Guénolé2023). There are two levels of laterality: individual-level laterality, where an individual displays a preference towards one side, and population-level laterality, where most individuals in a population exhibit behaviour that is consistently asymmetric towards the same side (Chapelain et al., Reference Chapelain, Pimbert, Aube, Perrocheau, Debunne, Bellido and Blois-Heulin2015; Versace et al., Reference Versace, Caffini, Werkhoven and de Bivort2020). In insects, behavioural asymmetries become have been reported during several tasks and in particular during mating phases (Takanashi et al., Reference Takanashi, Nakano, Surlykke, Tatsuta, Tabata, Ishikawa and Skals2010). These phases involve the development of premating and mating behaviours, characterised by lateralised movements, i.e. movements to the right or left (Kavallieratos et al., Reference Kavallieratos, Boukouvala, Gidari, Di Giuseppe, Canale and Benelli2023). These directional variations play a significant role in mating success, offering distinct differences in biological fitness (Vallortigara and Rogers, Reference Vallortigara and Rogers2005; Dadda et al., Reference Dadda, Zandona, Agrillo and Bisazza2009; Vallortigara and Rogers, Reference Vallortigara and Rogers2020). While research on lateralised traits has primarily focused on vertebrate animals (Stieger et al., Reference Stieger, Wesseler, Kaiser, Sachser and Richter2023; van Dijk et al., Reference van Dijk, Bhattacharjee, Belli and Massen2023; Wang et al., Reference Wang, Luo, Lin, Xu, Gu, Bu, Bai and Li2023), an increasing number of studies are shedding light on individual and population-level brain and behavioural asymmetries in various invertebrate species (Benelli et al., Reference Benelli, Romano, Stefanini, Kavallieratos, Athanassiou and Canale2017; Romano et al., Reference Romano, Benelli and Stefanini2017). The lateralisation of courtship and mating behaviour has been examined in several insect species, including hymenopteran parasitoids (Romano et al., Reference Romano, Benelli, Stefanini, Desneux, Ramirez-Romero, Canale and Lucchi2018) (Romano et al., Reference Romano, Benelli, Kavallieratos, Athanassiou, Canale and Stefanini2020), stored-product beetles (Kavallieratos et al., Reference Kavallieratos, Boukouvala, Gidari, Di Giuseppe, Canale and Benelli2023; Othman et al., Reference Othman, Elias and Zainalabidin2023), mosquitoes (Benelli, Reference Benelli2018), and a calliphorid fly (Benelli et al., Reference Benelli, Romano, Messing and Canale2015a). In this paper, we add to this growing body of data by investigating the lateralisation of courtship and mating behaviour in Ostrinia furnacalis Guenée (Lepidoptera: Crambidae). Exploring the behavioural ecology of an insect pest species holds promise for pioneering approaches within Integrated Pest Management (IPM), offering innovative strategies for pest control and conservation (Avosani et al., Reference Avosani, Nieri, Mazzoni, Anfora, Hamouche, Zippari, Vitale, Verrastro, Tarasco and D'Isita2023).

The Asian corn borer, O. furnacalis, is a polyphagous nocturnal moth, and a pest causing significant damage to major crops in Asia and Europe (Li et al., Reference Li, Feng, Ji, Huang and Tian2021; Kim et al., Reference Kim, Jung, Kim and Kim2022). It is known for its intricate mating rituals, where mate selection predominantly hinges on male age and vitality (Frolov et al., Reference Frolov, Shchenikova, Selitskaya, Grushevaya, Zhukovskaya, Fedoseev, Kuzmin, Lastushkina, Kurenshchikov and Kurenshchikov2022). Investigating the courtship of O. furnacalis, including the role of lateralisation, can yield valuable insights into effective strategies for population control and crop damage mitigation (Boukouvala et al., Reference Boukouvala, Kavallieratos, Canale and Benelli2022). Specifically, studying the sensory cues and behavioural elements involved in O. furnacalis mating behaviour can help identify potential targets for pest management, such as using pheromones or other attractants (Yao et al., Reference Yao, Zhou, Li, Liu, Zhao, Wei, Du and An2021). Variations in ultrasonic sounds and pheromones are closely related to each other in moth species and can profoundly impact mate recognition, reproductive isolation, and speciation (Takanashi et al., Reference Takanashi, Nakano, Surlykke, Tatsuta, Tabata, Ishikawa and Skals2010; Arminudin et al., Reference Arminudin, Wijonarko and Trisyono2020). Our study involved the exploration, observation, and quantification of lateralisation in the courtship and mating behaviour of O. furnacalis. Our goal was to uncover patterns of population-level lateralisation during courtship and mating behaviour and to elucidate how these variances might impact the mating success of male insects. The investigations of these selected lateralised behaviours during male–female interactions aim to enhance our understanding of O. furnacalis behavioural ecology and the significance of lateralised traits within this species.

Materials and methods

Experimental site

The study was conducted in the Agricultural Entomology and Pest Control laboratory and Conservation Tillage Pest and Disease Monitoring Base at Jilin Agricultural University (43.815°N, 125.398°E).

Insect culture

Insects were collected from maize fields (43.815°N, 125.391°E) during early August 2023 with pheromone traps (for male adults) and aerial nets (for female adults), and transported within a plastic container (height: width: length; 23 cm × 45 cm × 70 cm) to the laboratory for mating, approximately 3 km away from the maize fields. The insects were housed in mesh cloth cages (height: width: length; 16 cm × 16 cm × 16 cm; 13 adult parent pairs per cage), at a relative humidity (RH) of 65 ± 5% and a temperature of 26 ± 2 °C. A butter paper was placed on the upper side of the mesh cloth cage for egg laying. A diet comprising 10% sugar-soaked cotton balls (10 ml water) was provided to parent adults. After an incubation period of 2–4 days, eggs were collected and placed in a plastic container (height: width: length; 23 cm × 45 cm × 70 cm), where larvae were fed with a self-made artificial diet (water, wheat germ flour, yeast powder, agar, sucrose, vitamin C (VC), sorbic acid, and nipagin; Liu et al., Reference Liu, Feng, Abbas, Abbas, Hafeez, Han, Romano and Chen2023) until reaching the pupal stage.

Experimental setup for observation of courtship and mating behaviour

To prevent any premature mating interactions among the emerging adults, O. furnacalis pupae were individually isolated in plastic round cups with lids (3.5 cm diameter × 3.5 cm height), which had small holes and contained cotton inside to ensure proper air circulation and humidity access. Newly emerged adult male–female pairs were introduced into the experimental containers (height: width: length; 73 cm × 53 cm × 45 cm) to study courtship and mating behaviours. We observed lateralised courtship and mating behaviours in a total of 150 male–female pairs. To improve the precision of our observations, the experiment was replicated three times, each time with an approximate cohort of 50 adult male–female pairs. It is important to note that only adult pairs displaying mating interactions were included in the analysis; any pairs not displaying such behaviour were omitted from the final dataset. The final sample size for analysis comprised 119 male–female mating pairs (adult pairs exhibited mating interaction out of 150 male–female pairs), aggregated from all three independent repetitions.

A 12-hour observation was conducted for each of the three repetitions using a REOLINK® night vision camera (model number: Reolink Duo 2 Wifi; OS Supported: Windows, Mac, iOS, Android). The same container was used consistently for all three repetitions. The process involved conducting one repetition for 12 hours, removing adults, proceeding with the next repetition for another 12 hours, and repeating the cycle for the third repetition. The camera was equipped with 1/2.7” CMOS sensors and recorded video at a resolution of 4608 × 1728 (8.0 Megapixels) with a frame rate of 20 frames/second to record the insects’ behaviours. The experimental setup consisted of a large plastic container with two compartments, each maintained under controlled conditions of 65 ± 5% RH and a temperature of 26 ± 2 °C. The upper compartment (height: width: length; 63 cm × 53 cm × 45 cm) served as the habitat for the insects, while the inner compartment (height: width: length; 10 cm × 10 cm × 8 cm) housed the night vision camera. To ensure clear and unobstructed video recordings, the camera lens was positioned within the mating chamber. It was connected to an Android mobile phone with a dedicated Android application for seamless recording and data storage management. The night vision camera featured a memory card slot for directly storing recorded videos and captured pictures.

Throughout the observation period, the camera was placed approximately 1 m from the focal insects to optimise video quality and capture detailed behavioural patterns. Leveraging night vision technology, the insects’ activities were monitored during the dark period when their natural mating behaviours were most frequent. Following data collection, recorded videos were stored on a memory card for subsequent analysis. These videos were examined for courtship displays, mating sequences, and the manifestation of any lateral biases (fig. 1).

Figure 1. Experimental setup for observing courtship and mating behaviours in O. furnacalis.

After behavioural displays, observations were made regarding the male's selection of the side for approach to the female's posterior of the abdomen. Furthermore, the specific side chosen by the male for intromissive copulation at 180° turn was recorded; this manoeuvre is pivotal for facilitating the establishment of end-to-end genital linkage and initiating copulation. This evaluation sought to elucidate the potential influence of lateralised behaviours on the mating process in O. furnacalis (Table 1).

Table 1. Behavioural displays observed during courtship and mating behaviour of O. furnacalis

Statistical analysis

The impact of lateralisation on differences in the mean duration and/or number of courtship and mating behaviours acts was analysed using Origin Pro 2023b (Northampton, Massachusetts, USA) with non-parametric statistics (P < 0.05) because of non-normal (Shapiro–Wilk test, P < 0.05) data distribution and non-homoscedasticity (Levene's test, P < 0.05). Laterality differences between the numbers of males approaching the left or right side of the female, as well as the number of males turning 180° to the left or to the right in an attempt to copula during courtship interactions, were analysed using an Chi22) test with Yates’ correction (P < 0.05) (Loriaux, Reference Loriaux1971).

Results

Among the adults under observation, only 119 male–female pairs displayed mating behaviours and were consequently included in the analysis. When a male encounters a female, a sequence of distinct behaviours unfolds. Initially, the male engages in a sequence of actions, including ultrasonic courtship songs through wing vibrations, exhibiting male aggression towards the female, and softly tapping the female's body with his antennae. As the male approaches the tip of the female's abdomen, he carefully touches the posterior of her abdomen with his antennae. This interaction frequently elicits a response from the female, where she raises her abdomen, indicating her receptivity. Following this, the male may respond aggressively if met with rejection or if the female attempts to evade the courtship. During this phase, the male rotates his body, forming a 180 ° angle relative to the female (figs 2 and 3A-B). In the later stages of courtship, the female typically becomes motionless in response to the male's persistent courtship behaviours (Table 2). This motionlessness serves as a crucial signal, indicating her readiness to engage in end-to-end genital contact – a pivotal step in initiating copulation.

Figure 2. Ethogram depicting the courtship and mating sequence of the O. furnacalis. The proportion of adults displaying each behaviour is indicated by the thickness of each arrow (n = 119 observed mating pairs).

Figure 3. Mating success of O. furnacalis males showing (A) left or right-biased approaches to the female, and (B) left or right-biased turning displays; asterisks indicate a significant difference between left and right-biased acts (χ2 test with Yates’ correction, P < 0.05).

Table 2. Courtships behavioural displays of Ostrinia furnacalis showing side-biased approaches towards the females

Values are means followed by standard errors (SE) within each row, similar letters indicate no significant differences between side-biased parameters (Wilcoxon test, P < 0.05).

The success of mating was notably higher when O. furnacalis males approached females from the left side during sexual interactions (χ2 = 6.700; df = 1; P < 0.0001), while approaches from the right side did not significantly impact mating success (χ2 = 0.0001; df = 1; P = 0.988) (Table 2). Additionally, turning direction to the left while attempting copula resulted in a higher male mating success (χ2 = 8.130; df = 1; P < 0.0001) compared to males displaying a right-biased turning behaviour (χ2 = 1.944; df = 1; P = 0.717). (See Table 3.)

Table 3. Courtships and mating behavioural displays of O. furnacalis showing lateralised turning behaviour

Values are means followed by standard errors (SE); within each row, different letters indicate significant differences among side-biased parameters (Kruskal–Wallis test, P < 0.05).

Mating success in males was significantly influenced by ultrasonic courtship songs (χ2 = 15.130; df = 1; P < 0.0001), male aggression towards female displayed during courtship (χ2 = 5.590; df = 1; P = 0.011), female courtship rejection or escape (χ2 = 4.640; df = 1; P = 0.051), as well as the number of the male copulation attempts (χ2 = 6.504; df = 1; P = 0.021). The male's mating success, however, remained unaffected by the duration of the antennal tapping by the male on the female (χ2 = 2.001; df = 1; P = 0.067) and duration of the antennal tapping by the male on the female (χ2 = 1.651; df = 1; P = 0.922). (See Table 2.)

No significant differences between males approaching females with left- or right-biased directions were observed in the duration of the male's ultrasonic courtship songs (χ2 = 1.900; df = 1; P = 0.071), male aggression towards female for courtship (χ2 = 1.504; df = 1; P = 0.091), the duration of the male antennal contact with the posterior of female (χ2 = 0.071; df = 1; P = 0.990), (χ2 = 0.043; df = 1; P = 0.720), and female courtship rejection or escape (χ2 = 0.904; df = 1; P = 0.661), female motionlessness in response to male courtship behaviours (χ2 = 0.029; df = 1; P = 0.000), the number of the male copulation attempts (χ2 = 0.027; df = 1; P = 0.891), as well as the duration of intromissive copulation (χ2 = 0.026; df = 1; P = 0.876). (See Table 2.)

Turning direction was not associated with the duration of the male's ultrasonic courtship songs (χ2 = 0.016; df = 1; P = 0.897), male aggression towards female during courtship (χ2 = 3.969; df = 2; P = 0.137), the duration of the male antennal contact with the posterior of female (χ2 = 1.147; df = 2; P = 0.563), male aggression towards female in response to courtship rejection or escape (χ2 = 3.969; df = 2; P = 0.137), and female motionlessness in response to male courtship behaviours (χ2 = 5.128; df = 2; P = 0.077), the number of the male copulation attempts (χ2 = 3.527; df = 1; P = 0.060), or the duration of intromissive copulation (χ2 = 0.484; df = 1; P = 0.486). (See Table 3.) However, the number of male copulation attempts was significantly affected by the side chosen by the male to turn 180° and attempt copulation (χ2 = 16.017; df = 2; P < 0.0001). Males that turned 180° from the female left side performed significantly more attempts to insert their aedeagus into the female's genital chamber, if compared to right-biased turning males, which started copulation earlier with lower copulation attempts (Table 3).

Discussion

In the context of lateralised courtship and mating behaviours in male adults of O. furnacalis, various critical behaviours come into play to ensure successful mating, as reported in recent research (Sun et al., Reference Sun, Bu, Su, Guo, Gao and Wu2023). Our research has discovered novel lateralisation in mating behaviours of O. furnacalis adult males and females, particularly in response to female calling behaviours for mating. Upon encountering a female, the male engages in a series of distinct actions. In the results section, the whole sequence of ethological units is described. Our general observations align with previous studies on other Ostrinia species, emphasising the consistency of these courtship and mating behaviours, specifically the role of male ultrasonic courtship songs across this group of insects (Nakano et al., Reference Nakano, Takanashi, Skals, Surlykke and Ishikawa2010; Nakano et al., Reference Nakano, Takanashi, Surlykke, Skals and Ishikawa2013; Nakano and Nagamine, Reference Nakano and Nagamine2019; Rizvi et al., Reference Rizvi, George, Reddy, Zeng and Guerrero2021; Zweerus et al., Reference Zweerus, van Wijk, Schal and Groot2021). Specifically, our results on the importance of laterality find resonance with numerous studies on lateralisation in mating behaviours in other insects species, including the rock ant (Temnothorax albipennis) (Hunt et al., Reference Hunt, Dornan, Sendova-Franks and Franks2018), Khapra beetle (Trogoderma granarium) (Kavallieratos et al., Reference Kavallieratos, Boukouvala, Gidari, Di Giuseppe, Canale and Benelli2023), mosquitoes (Culex pipiens) (Benelli, Reference Benelli2018), olive fruit fly (Bactrocera oleae) (Benelli et al., Reference Benelli, Romano, Messing and Canale2015a; Zaynagutdinova et al., Reference Zaynagutdinova, Kölzsch, Müskens, Vorotkov, Sinelshikova, Giljov and Karenina2022) and Mediterranean fruit fly (Ceratitis capitata) (Benelli et al., Reference Benelli, Donati, Romano, Stefanini, Messing and Canale2015b). This broader alignment with the literature reinforces the generalisability of our findings to a broader context of insect behaviour and adds to the growing body of knowledge in this field.

In the present study, we have identified two specific behavioural displays in O. furnacalis that exhibit within-population dimorphism in laterality. It was consistently observed that a significant majority of male O. furnacalis, during courtship and mating, preferred to position themselves at the tip of the female's abdomen. In doing so, they occasionally engaged in antennal tapping and palpation on the left side of the female's body. Additionally, males strongly preferred clockwise and anti-clockwise rotations (right and left turns) when forming a 180-degree angle with the female's body, which is crucial for the end-to-end genital linkage. Notably, we observed that males approaching females from the right-side were primarily left-biased in their 180° turning, while those approaching from the left-side exhibited a right-biased in their turning behaviour. It is important to underline that these lateralised traits did not substantially impact the main behavioural parameters characterising courtship and mating in O. furnacalis. However, it is noteworthy that males executing a 180° turn from their left-side appeared to make fewer copulation attempts, suggesting a potentially better orientation and efficiency in achieving genital linkage among right-biased males. Many studies agree with our finding in turning 180° while mating with various insects (Benelli et al., Reference Benelli, Romano, Messing and Canale2015a; Chivers et al., Reference Chivers, McCormick, Warren, Allan, Ramasamy, Arvizu, Glue and Ferrari2017; Kiss et al., Reference Kiss, Toth, Jocsak, Bartha, Frenyo, Barany, Horvath and Zsarnovszky2020; Romano et al., Reference Romano, Benelli and Stefanini2022)

Significantly, our study unveiled a correlation between mating success and lateralisation. Males that approached females from the right-side and those that preferred leftward turning exhibited significantly higher mating success rates. This finding marks the first evidence of population-level lateralised mating traits in O. furnacalis, a species previously known primarily for motor bias in lateralisation. Our results align with a substantial body of literature highlighting the prevalence of population-level lateralised traits in social and solitary insect species (Anfora et al., Reference Anfora, Frasnelli, Maccagnani, Rogers and Vallortigara2010; Sakurai and Ikeda, Reference Sakurai and Ikeda2022). Recent studies have reported lateralised traits related to courtship, mating, and genital morphology (Schilthuizen, Reference Schilthuizen2013) in various insects, including lesser mealworm beetle (Alphitobius diaperinus) (Calla-Quispe et al., Reference Calla-Quispe, Irigoin, Mansurova, Martel and Ibáñez2023), earwigs (Nala nepalensis) (Kamimura et al., Reference Kamimura, Matsumura, Yang and Gorb2021), rusty grain beetle (Cryptolestes ferrugineus) (Boukouvala et al., Reference Boukouvala, Kavallieratos, Canale and Benelli2022), encyrtid parasitoids (Anagyrus sp.) (Romano et al., Reference Romano, Benelli, Stefanini, Desneux, Ramirez-Romero, Canale and Lucchi2018), green bottle fly (Lucilia sericata) (Romano et al., Reference Romano, Benelli and Stefanini2021), and Drosophila melanogaster (Versace et al., Reference Versace, Caffini, Werkhoven and de Bivort2020; Lapraz et al., Reference Lapraz, Boutres, Fixary-Schuster, De Queiroz, Plaçais, Cerezo, Besse, Préat and Noselli2023). Our research unveils the existence of lateralised courtship and mating behaviours in O. furnacalis, enriching our comprehension of this species beyond mere motor biases previously reported. This discovery resonates with a broader trend of population-level lateralisation seen across various insect species, underscoring the pivotal role of lateralisation in insect reproductive behaviours.

Theoretical models propose that population-level lateralisation is more likely to develop in social species. The reasoning behind this hypothesis lies in the potential benefits of lateralisation in social interactions (Rogers et al., Reference Rogers, Rigosi, Frasnelli and Vallortigara2013; Frasnelli and Vallortigara, Reference Frasnelli and Vallortigara2018; Ocklenburg et al., Reference Ocklenburg, El Basbasse, Ströckens and Müller-Alcazar2023; Tonello and Vallortigara, Reference Tonello and Vallortigara2023). In social insects, individuals often need to coordinate their behaviours, such as during group movements, foraging, or communication (Johnson, Reference Johnson2010; Feinerman and Korman, Reference Feinerman and Korman2017). Lateralisation, or the consistent preference for using one side of the body or brain, can facilitate efficient and synchronised interactions within the population. This may lead to improved coordination, reduced ambiguity in communication signals, and enhanced overall social cohesion (Frasnelli and Vallortigara, Reference Frasnelli and Vallortigara2018). While the specific mechanisms and advantages may vary across species, the underlying concept is that in social environments, population-level lateralisation could confer adaptive advantages that promote effective group functioning and communication (Vallortigara, Reference Vallortigara2006). However, in many insect species (such as O. furnacalis), the common and intense interactions among individuals, including numerous conflicts and mating events, as well as encounters with other species like predators and host plants, may help explain the widespread occurrence of population-level lateralisation (Casanova, Reference Casanova2020; Manns, Reference Manns, Vonk and Shackelford2022). The theory does not necessarily suggest that social species require population-level lateralisation, but it posits that lateralisation might emerge as an Evolutionary Stable Strategy (ESS) either at the individual or population level, depending on the specific context (Rogers et al., Reference Rogers, Frasnelli and Versace2016; Colombo, Reference Colombo2023; Jacobs and Oosthuizen, Reference Jacobs and Oosthuizen2023).

The discovery of lateralised courtship and mating behaviours across different insect orders suggests that this trait could serve as a pivotal component in the ESS governing the reproductive behaviour of these species (Vidal-Abarca Gutierrez et al., Reference Vidal-Abarca Gutierrez, Nicolás-Ruiz, Sánchez-Montoya and Suárez Alonso2023), While much of this research has traditionally been conducted in laboratory settings to understand the relevance of brain lateralisation as an adaptation to ecological demands (Manns, Reference Manns2021), our study also focuses explicitly on population-level lateralised courtship and mating in O. furnacalis. This provides valuable insights, demonstrating a noteworthy parallel with several vertebrates and invertebrates that exhibit lateral biases in their natural environments, unconstrained by laboratory conditions (Ventolini et al., Reference Ventolini, Ferrero, Sponza, Della Chiesa, Zucca and Vallortigara2005; Koboroff et al., Reference Koboroff, Kaplan and Rogers2008). This study, revealing asymmetries in the behaviour of O. furnacalis, supports the hypothesis that lateralisation is a widespread phenomenon and emphasises the need for increased attention to this topic among behavioural biologists in the context of pest management and ecological studies.

In conclusion, this study provides evidence of lateralised courtship and mating behaviours at the population level in O. furnacalis, offering a contribution to the understanding of these behaviours. Our research advances our fundamental knowledge of the courtship and mating behaviour of O. furnacalis, shedding light on previously unexplored aspects of its reproductive biology. The new insights gained into the reproductive behaviour of O. furnacalis may also hold practical implication by identifying behavioural traits suitable for assessing the quality of mass-reared individuals in pest control programs. Comprehending population-level lateralisation enables the identification of individuals with improved coordination and communication skills. This understanding holds promise for enhancing the effectiveness of pest management strategies by facilitating targeted releases.

Prior to this study, there were no attempts to evaluate the existence and functional importance of lateralised traits within the Crambidae. To advance our understanding, further research efforts need to extend beyond the laboratory setting and into the field to explore the existence of these lateralisation traits in O. furnacalis under natural conditions. The goal of these investigations is to offer a more thorough understanding of the distinct lateralisation traits displayed by this species. The quantification of mating displays in this laboratory study establishes a foundation for further research, enabling future comparative analyses with other insect species. This sets the stage for broader insights into the evolutionary and ecological implications of lateralisation among insect populations.

Availability of data and materials

Not applicable.

Acknowledgements

This work was supported by the Ministry of Science and Technology of China (2022YFD1500701).

Authors’ contributions

Sohail Abbas: Conceptualisation, Writing-Original Draft, Methodology, Data Analysis and Curation; Aleena Alam: Schematic Diagram and Data Curation, Muneer Abbas: Writing-Review and Editing; Arzlan Abbas: Writing-Review and Editing; Jamin Ali: Writing-Review and Editing; Menno Schilthuizen: Critically Revised Manuscript; Donato Romano: Methodology, Critically Revised Manuscript; Chen Ri Zhao: Supervision, Funding, Resources and Writing-Review and Editing.

Competing interests

None.

Ethical approval

Not applicable.

References

Anfora, G, Frasnelli, E, Maccagnani, B, Rogers, LJ and Vallortigara, G (2010) Behavioural and electrophysiological lateralization in a social (Apis mellifera) but not in a non-social (Osmia cornuta) species of bee. Behavioural Brain Research 206, 236239.10.1016/j.bbr.2009.09.023CrossRefGoogle Scholar
Arminudin, AT, Wijonarko, A and Trisyono, YA (2020) Ultrastructure characters and partial mtDNA-COI haplotypes of Asian corn borer, Ostrinia furnacalis (Guenée)(Lepidoptera: Crambidae) from Indonesia. Biodiversitas Journal of Biological Diversity 21, 29142922.10.13057/biodiv/d210707CrossRefGoogle Scholar
Avosani, S, Nieri, R, Mazzoni, V, Anfora, G, Hamouche, Z, Zippari, C, Vitale, ML, Verrastro, V, Tarasco, E and D'Isita, I (2023) Intruding into a conversation: how behavioral manipulation could support management of Xylella fastidiosa and its insect vectors. Journal of Pest Science 97, 117.Google Scholar
Benelli, G (2018) Mating behavior of the West Nile virus vector Culex pipiens–role of behavioral asymmetries. Acta Tropica 179, 8895.10.1016/j.actatropica.2017.12.024CrossRefGoogle ScholarPubMed
Benelli, G, Romano, D, Messing, RH and Canale, A (2015a) Population-level lateralized aggressive and courtship displays make better fighters not lovers: evidence from a fly. Behavioural Processes 115, 163168.10.1016/j.beproc.2015.04.005CrossRefGoogle Scholar
Benelli, G, Donati, E, Romano, D, Stefanini, C, Messing, RH and Canale, A (2015b) Lateralisation of aggressive displays in a tephritid fly. The Science of Nature 102, 19.10.1007/s00114-014-1251-6CrossRefGoogle Scholar
Benelli, G, Romano, D, Stefanini, C, Kavallieratos, NG, Athanassiou, CG and Canale, A (2017) Asymmetry of mating behaviour affects copulation success in two stored-product beetles. Journal of Pest Science 90, 547556.10.1007/s10340-016-0794-zCrossRefGoogle Scholar
Boukouvala, MC, Kavallieratos, NG, Canale, A and Benelli, G (2022) Functional asymmetries routing the mating behavior of the rusty grain beetle, Cryptolestes ferrugineus (Stephens)(Coleoptera: Laemophloeidae). Insects 13, 699.10.3390/insects13080699CrossRefGoogle ScholarPubMed
Calla-Quispe, E, Irigoin, E, Mansurova, M, Martel, C and Ibáñez, AJ (2023) Lateralized movements during the mating behavior, which are associated with sex and sexual experience, increase the mating success in Alphitobius diaperinus (Coleoptera: Tenebrionidae). Insects 14, 806.10.3390/insects14100806CrossRefGoogle ScholarPubMed
Casanova, C (2020) Abstracts of the 7th Iberian congress of primatology. Folia Primatologica 91, 512540.Google Scholar
Chapelain, A, Pimbert, P, Aube, L, Perrocheau, O, Debunne, G, Bellido, A and Blois-Heulin, C (2015) Can population-level laterality stem from social pressures? Evidence from cheek kissing in humans. PLoS One 10, e0124477.10.1371/journal.pone.0124477CrossRefGoogle ScholarPubMed
Chivers, DP, McCormick, MI, Warren, DT, Allan, BJ, Ramasamy, RA, Arvizu, BK, Glue, M and Ferrari, MC (2017) Competitive superiority versus predation savvy: the two sides of behavioural lateralization. Animal Behaviour 130, 915.10.1016/j.anbehav.2017.05.006CrossRefGoogle Scholar
Colombo, JA (2023) Evolution and the Human-Animal Drive to Conflict: A Psychobiological Perspective. Taylor & Francis, London: Routledge.10.4324/9781003387695CrossRefGoogle Scholar
Dadda, M, Zandona, E, Agrillo, C and Bisazza, A (2009) The costs of hemispheric specialization in a fish. Proceedings of the Royal Society B: Biological Sciences 276, 43994407.10.1098/rspb.2009.1406CrossRefGoogle ScholarPubMed
David Fernandes, AS and Niven, JE (2020) Lateralization of short-and long-term visual memories in an insect. Proceedings of the Royal Society B 287, 20200677.10.1098/rspb.2020.0677CrossRefGoogle ScholarPubMed
Desaunay, P, Guillery, B, Moussaoui, E, Eustache, F, Bowler, DM and Guénolé, F (2023) Brain correlates of declarative memory atypicalities in autism: a systematic review of functional neuroimaging findings. Molecular Autism 14, 132.10.1186/s13229-022-00525-2CrossRefGoogle ScholarPubMed
Feinerman, O and Korman, A (2017) Individual versus collective cognition in social insects. Journal of Experimental Biology 220, 7382.10.1242/jeb.143891CrossRefGoogle ScholarPubMed
Frasnelli, E and Vallortigara, G (2018) Individual-level and population-level lateralization: two sides of the same coin. Symmetry 10, 739.10.3390/sym10120739CrossRefGoogle Scholar
Frolov, A, Shchenikova, A, Selitskaya, O, Grushevaya, I, Zhukovskaya, M, Fedoseev, N, Kuzmin, A, Lastushkina, E, Kurenshchikov, D and Kurenshchikov, V (2022) Asian corn borer (Ostrinia furnacalis Gn., Lepidoptera: Crambidae): attraction to a bisexual lure and comparison of performance with synthetic sex pheromone. Acta Phytopathologica et Entomologica Hungarica 57, 148164.10.1556/038.2022.00159CrossRefGoogle Scholar
Güntürkün, O, Ströckens, F and Ocklenburg, S (2020) Brain lateralization: a comparative perspective. Physiological Reviews 100, 1019–1063.10.1152/physrev.00006.2019CrossRefGoogle ScholarPubMed
Hunt, ER, Dornan, C, Sendova-Franks, AB and Franks, NR (2018) Asymmetric ommatidia count and behavioural lateralization in the ant Temnothorax albipennis. Scientific Reports 8, 5825.10.1038/s41598-018-23652-4CrossRefGoogle ScholarPubMed
Jacobs, PJ and Oosthuizen, MK (2023) Laterality in the Damaraland mole-rat: insights from a Eusocial Mammal. Animals 13, 627.10.3390/ani13040627CrossRefGoogle ScholarPubMed
Johnson, BR (2010) Task partitioning in honey bees: the roles of signals and cues in group-level coordination of action. Behavioral Ecology 21, 13731379.10.1093/beheco/arq138CrossRefGoogle Scholar
Kamimura, Y, Matsumura, Y, Yang, C-CS and Gorb, SN (2021) Random or handedness? Use of laterally paired penises in Nala earwigs (Insecta: Dermaptera: Labiduridae). Biological Journal of the Linnean Society 134, 716731.10.1093/biolinnean/blab111CrossRefGoogle Scholar
Kavallieratos, NG, Boukouvala, MC, Gidari, DLS, Di Giuseppe, G, Canale, A and Benelli, G (2023) Does cross-mating affect behavioral asymmetries and mating success of khapra beetle (Trogoderma granarium) strains? Entomologia Generalis 43, 409419.10.1127/entomologia/2023/1729CrossRefGoogle Scholar
Kim, EY, Jung, JK, Kim, IH and Kim, Y (2022) Chymotrypsin is a molecular target of insect resistance of three corn varieties against the Asian corn borer, Ostrinia furnacalis. PLoS One 17, e0266751.10.1371/journal.pone.0266751CrossRefGoogle ScholarPubMed
Kiss, DS, Toth, I, Jocsak, G, Bartha, T, Frenyo, LV, Barany, Z, Horvath, TL and Zsarnovszky, A (2020) Metabolic lateralization in the hypothalamus of male rats related to reproductive and satiety states. Reproductive Sciences 27, 11971205.10.1007/s43032-019-00131-3CrossRefGoogle ScholarPubMed
Koboroff, A, Kaplan, G and Rogers, LJ (2008) Hemispheric specialization in Australian magpies (Gymnorhina tibicen) shown as eye preferences during response to a predator. Brain Research Bulletin 76, 304306.10.1016/j.brainresbull.2008.02.015CrossRefGoogle ScholarPubMed
Labache, L, Ge, T, Yeo, BT and Holmes, AJ (2023) Language network lateralization is reflected throughout the macroscale functional organization of cortex. Nature Communications 14, 3405.10.1038/s41467-023-39131-yCrossRefGoogle ScholarPubMed
Lapraz, F, Boutres, C, Fixary-Schuster, C, De Queiroz, B, Plaçais, P, Cerezo, D, Besse, F, Préat, T and Noselli, S (2023) Asymmetric activity of NetrinB controls laterality of the Drosophila brain. Nature Communications 14, 1052.10.1038/s41467-023-36644-4CrossRefGoogle ScholarPubMed
Li, G, Feng, H, Ji, T, Huang, J and Tian, C (2021) What type of Bt corn is suitable for a region with diverse lepidopteran pests: a laboratory evaluation. GM Crops & Food 12, 115124.10.1080/21645698.2020.1831728CrossRefGoogle ScholarPubMed
Liu, J-L, Feng, X, Abbas, A, Abbas, S, Hafeez, F, Han, X, Romano, D and Chen, RZ (2023) Larval competition analysis and its effect on growth of Ostrinia furnacalis (Lepidoptera: Crambidae) at natural conditions in Northeast China. Environmental Entomology 52, 970982.10.1093/ee/nvad089CrossRefGoogle ScholarPubMed
Loriaux, M (1971) RR Sokal and FJ Rohlf Biometry. The principles and practice of statistics in biological research. San Francisco, WH Freeman and Company, 1969, XXI p. 776 p., 126/-.-FJ Rohlf and RR Sokal statistical tables. San Francisco, WH Freeman and Company, 1969, XI p. 253 p., $2.75. Recherches Économiques de Louvain/Louvain Economic Review 37, 461462.10.1017/S0770451800026853CrossRefGoogle Scholar
Manns, M (2021) Laterality for the next decade: costs and benefits of neuronal asymmetries–putting lateralization in an evolutionary context. Laterality 26, 315318.10.1080/1357650X.2021.1886110CrossRefGoogle Scholar
Manns, M (2022) Hemispheric Specialization. In Vonk, J., Shackelford, T.K. (eds), Encyclopedia of Animal Cognition and behavior. Cham: Springer International Publishing, pp. 30623071.10.1007/978-3-319-55065-7_1392CrossRefGoogle Scholar
Nakano, R and Nagamine, K (2019) Loudness-duration tradeoff in ultrasonic courtship songs of moths. Frontiers in Ecology and Evolution 7, 244.10.3389/fevo.2019.00244CrossRefGoogle Scholar
Nakano, R, Takanashi, T, Skals, N, Surlykke, A and Ishikawa, Y (2010) Ultrasonic courtship songs of male Asian corn borer moths assist copulation attempts by making the females motionless. Physiological Entomology 35, 7681.10.1111/j.1365-3032.2009.00712.xCrossRefGoogle Scholar
Nakano, R, Takanashi, T, Surlykke, A, Skals, N and Ishikawa, Y (2013) Evolution of deceptive and true courtship songs in moths. Sci. Rep 3, 2003.10.1038/srep02003CrossRefGoogle ScholarPubMed
Ocklenburg, S, El Basbasse, Y, Ströckens, F and Müller-Alcazar, A (2023) Hemispheric asymmetries and brain size in mammals. Communications Biology 6, 521.10.1038/s42003-023-04894-zCrossRefGoogle ScholarPubMed
Othman, N, Elias, NH and Zainalabidin, N (2023) Wood vinegar as an alternative insecticide in controlling rice weevil, Sitophylus oryzae (Coleoptera: Curculionidae). Advances in Agricultural and Food Research Journal 4, a0000315.10.36877/aafrj.a0000315CrossRefGoogle Scholar
Rizvi, SAH, George, J, Reddy, GV, Zeng, X and Guerrero, A (2021) Latest developments in insect sex pheromone research and its application in agricultural pest management. Insects 12, 484.10.3390/insects12060484CrossRefGoogle ScholarPubMed
Rogers, LJ, Rigosi, E, Frasnelli, E and Vallortigara, G (2013) A right antenna for social behaviour in honeybees. Scientific Reports 3, 2045.10.1038/srep02045CrossRefGoogle ScholarPubMed
Rogers, LJ, Frasnelli, E and Versace, E (2016) Lateralized antennal control of aggression and sex differences in red mason bees, Osmia bicornis. Scientific Reports 6, 29411.10.1038/srep29411CrossRefGoogle ScholarPubMed
Romano, D, Benelli, G and Stefanini, C (2017) Escape and surveillance asymmetries in locusts exposed to a Guinea fowl-mimicking robot predator. Scientific Reports 7, 12825.10.1038/s41598-017-12941-zCrossRefGoogle ScholarPubMed
Romano, D, Benelli, G, Stefanini, C, Desneux, N, Ramirez-Romero, R, Canale, A and Lucchi, A (2018) Behavioral asymmetries in the mealybug parasitoid Anagyrus sp. near pseudococci: does lateralized antennal tapping predict male mating success? Journal of Pest Science 91, 341349.10.1007/s10340-017-0903-7CrossRefGoogle Scholar
Romano, D, Benelli, G, Kavallieratos, NG, Athanassiou, CG, Canale, A and Stefanini, C (2020) Beetle-robot hybrid interaction: sex, lateralization and mating experience modulate behavioural responses to robotic cues in the larger grain borer Prostephanus truncatus (Horn). Biological Cybernetics 114, 473483.10.1007/s00422-020-00839-5CrossRefGoogle ScholarPubMed
Romano, D, Benelli, G and Stefanini, C (2021) Opposite valence social information provided by bio-robotic demonstrators shapes selection processes in the green bottle fly. Journal of the Royal Society Interface 18, 20210056.10.1098/rsif.2021.0056CrossRefGoogle ScholarPubMed
Romano, D, Benelli, G and Stefanini, C (2022) Lateralization of courtship traits impacts pentatomid male mating success—evidence from field observations. Insects 13, 172.10.3390/insects13020172CrossRefGoogle ScholarPubMed
Sakurai, Y and Ikeda, Y (2022) Visual and brain lateralization during the posthatching phase in squid under solitary and group conditions. Animal Behaviour 183, 1328.10.1016/j.anbehav.2021.10.015CrossRefGoogle Scholar
Schilthuizen, M (2013) Something gone awry: unsolved mysteries in the evolution of asymmetric animal genitalia. Animal Biology 63, 120.10.1163/15707563-00002398CrossRefGoogle Scholar
Stieger, B, Wesseler, Y, Kaiser, S, Sachser, N and Richter, SH (2023) Behavioral lateralization of mice varying in serotonin transporter genotype. Frontiers in Behavioral Neuroscience 16, 1095567.10.3389/fnbeh.2022.1095567CrossRefGoogle ScholarPubMed
Sun, H, Bu, L-A, Su, S-C, Guo, D, Gao, C-F and Wu, S-F (2023) Knockout of the odorant receptor co-receptor, orco, impairs feeding, mating and egg-laying behavior in the fall armyworm Spodoptera frugiperda. Insect Biochemistry and Molecular Biology 152, 103889.10.1016/j.ibmb.2022.103889CrossRefGoogle ScholarPubMed
Takanashi, T, Nakano, R, Surlykke, A, Tatsuta, H, Tabata, J, Ishikawa, Y and Skals, N (2010) Variation in courtship ultrasounds of three Ostrinia moths with different sex pheromones. PLoS One 5, e13144.10.1371/journal.pone.0013144CrossRefGoogle ScholarPubMed
Tonello, L and Vallortigara, G (2023) Evolutionary models of lateralization: steps toward stigmergy? Frontiers in Behavioral Neuroscience 17, 1121335.10.3389/fnbeh.2023.1121335CrossRefGoogle ScholarPubMed
Vallortigara, G (2006) The evolutionary psychology of left and right: costs and benefits of lateralization. Developmental Psychobiology: The Journal of the International Society for Developmental Psychobiology 48, 418427.10.1002/dev.20166CrossRefGoogle ScholarPubMed
Vallortigara, G and Rogers, L (2005) Survival with an asymmetrical brain: advantages and disadvantages of cerebral lateralization. Behavioral and Brain Sciences 28, 595596.10.1017/S0140525X05000105CrossRefGoogle ScholarPubMed
Vallortigara, G and Rogers, LJ (2020) A function for the bicameral mind. Cortex 124, 274285.10.1016/j.cortex.2019.11.018CrossRefGoogle ScholarPubMed
van Dijk, ES, Bhattacharjee, D, Belli, E and Massen, JJ (2023) Hand preference predicts behavioral responses to threats in Barbary macaques. American Journal of Primatology 85, e23499.10.1002/ajp.23499CrossRefGoogle ScholarPubMed
Ventolini, N, Ferrero, EA, Sponza, S, Della Chiesa, A, Zucca, P and Vallortigara, G (2005) Laterality in the wild: preferential hemifield use during predatory and sexual behaviour in the black-winged stilt. Animal Behaviour 69, 10771084.10.1016/j.anbehav.2004.09.003CrossRefGoogle Scholar
Versace, E, Caffini, M, Werkhoven, Z and de Bivort, BL (2020) Individual, but not population asymmetries, are modulated by social environment and genotype in Drosophila melanogaster. Scientific Reports 10, 4480.10.1038/s41598-020-61410-7CrossRefGoogle Scholar
Vidal-Abarca Gutierrez, MR, Nicolás-Ruiz, N, Sánchez-Montoya, MdM and Suárez Alonso, ML (2023) Ecosystem services provided by dry river socio-ecological systems and their drivers of change. Hydrobiologia 850, 25852607.10.1007/s10750-022-04915-8CrossRefGoogle Scholar
Wang, L, Luo, Y, Lin, H, Xu, N, Gu, Y, Bu, H, Bai, Y and Li, Z (2023) Performance on inhibitory tasks does not relate to handedness in several small groups of Callitrichids. Animal Cognition 26, 415423.10.1007/s10071-022-01682-wCrossRefGoogle Scholar
Yao, S, Zhou, S, Li, X, Liu, X, Zhao, W, Wei, J, Du, M and An, S (2021) Transcriptome analysis of Ostrinia furnacalis female pheromone gland: esters biosynthesis and requirement for mating success. Frontiers in Endocrinology 12, 736906.10.3389/fendo.2021.736906CrossRefGoogle ScholarPubMed
Zaynagutdinova, E, Kölzsch, A, Müskens, GJ, Vorotkov, M, Sinelshikova, A, Giljov, A and Karenina, K (2022) Visual lateralization in flight: lateral preferences in parent-offspring relative positions in geese. Ethology 128, 159167.10.1111/eth.13252CrossRefGoogle Scholar
Zweerus, NL, van Wijk, M, Schal, C and Groot, AT (2021) Experimental evidence for female mate choice in a noctuid moth. Animal Behaviour 179, 113.10.1016/j.anbehav.2021.06.022CrossRefGoogle Scholar
Figure 0

Figure 1. Experimental setup for observing courtship and mating behaviours in O. furnacalis.

Figure 1

Table 1. Behavioural displays observed during courtship and mating behaviour of O. furnacalis

Figure 2

Figure 2. Ethogram depicting the courtship and mating sequence of the O. furnacalis. The proportion of adults displaying each behaviour is indicated by the thickness of each arrow (n = 119 observed mating pairs).

Figure 3

Figure 3. Mating success of O. furnacalis males showing (A) left or right-biased approaches to the female, and (B) left or right-biased turning displays; asterisks indicate a significant difference between left and right-biased acts (χ2 test with Yates’ correction, P < 0.05).

Figure 4

Table 2. Courtships behavioural displays of Ostrinia furnacalis showing side-biased approaches towards the females

Figure 5

Table 3. Courtships and mating behavioural displays of O. furnacalis showing lateralised turning behaviour