Laboratory Evidence of 2-Isobutyl-3-methoxypyrazine as a Male-Released Aggregative Cue in Labidostomis lusitanica (Germar) (Coleoptera: Chrysomelidae)

Simple Summary The leaf beetle Labidostomis lusitanica (Germar) (Coleoptera: Chrysomelidae) is a voracious defoliator beetle regarded as a threat for pistachio (Pistacia vera) crops in Spain. During late April–early June, field aggregates containing both sexes are commonly found in pistachio leaves. Males collected from these aggregates release a sex-specific compound, namely 2-isobutyl-3-methoxypyrazine, that elicits both a strong electrophysiological response and positive chemotactic behavior in males and females. Altogether, our findings suggest that 2-isobutyl-3-methoxypyrazine may act as an aggregative cue, although further field assays are required to address the true role of the compound in natural conditions. Abstract In spite of its incidence on pistachio trees, the chemical ecology of Labidostomis lusitanica (Germar) (Coleoptera: Chrysomelidae) has been neglected so far. In this work, we provide the first evidence of a biologically active male-specific compound that may be promoting field aggregation. Headspace collections through solid-phase microextraction from feral males and females reported the presence of 2-isobutyl-3-methoxypyrazine exclusively in males. Electroantennographic recordings revealed that males and females responded in a dose-dependent manner to increasing stimuli of 2-isobutyl-3-methoxypyrazine, with females overall displaying a higher response than males. In dual-choice tests, both males and females showed a significant preference for the compound in comparison to a pure air stimulus. In light of these results, the possible role of 2-isobutyl-3-methoxypyrazine as an aggregation cue in L. lusitanica is discussed.


Introduction
Pistachio (Pistacia vera L.) is a species native to central and southwestern Asia that is cultivated in some Mediterranean countries (Spain, Italy, Greece, Turkey, Tunisia), the Middle East (Iran, Syria), the United States (California and Arizona) and Australia [1][2][3].
Due to the quality of the edible nut, it is a species with a high commercial value worldwide.
In Spain, the European country with the greatest pistachio crop area, there is still a lack of knowledge on the insect pests that may threaten pistachio production [8,16]. Recently, a comprehensive study conducted by Gómez and coworkers highlighted the leaf beetle Labidostomis lusitanica (Germar) (Coleoptera: Chrysomelidae) as a potential serious threat for pistachio production in the Iberian Peninsula [17]. L. lusitanica is a polyphagous leaf beetle that feeds not only on pistachio, but also on Quercus L., Salix L. and Populus L., and on the herbaceous genera Rumex L. and Polygonum L. In pistachio plantations, it is considered a voracious species that may defoliate young trees in a few hours [17]. The species is found mostly in the eastern and southern part of the Iberian Peninsula, overlapping with pistachio crops [17]. During late April-early June, evenly distributed aggregates containing both sexes are commonly found, in which they feed, mate and lay eggs for a period of 4-5 weeks, and, subsequently, the individuals disperse across the crop. This behavior led us to suspect the existence of a possible aggregation pheromone in the species.
Hence, the aim of the current work was to isolate and identify the intraspecific chemical cues mediating this aggregation. For this purpose, we (a) characterized the volatile profile of both aggregative males and females, (b) measured the peripheral olfaction of a male-specific compound by means of electroantennographic recordings and, finally, (c) assessed the behavioral response of both sexes to the compound under laboratory conditions. Determining those chemical cues involved in the field aggregation of the insect would provide valuable knowledge for the further development of pheromone-based monitoring or mass trapping tools, in order to prevent the noxious effect of L. lusitanica on pistachio crops.

Insects
Feral aggregated L. lusitanica males and females were collected from 6th to 24th May 2021 in an organic farming-based pistachio orchard (0.36 ha) located in "El Chaparrillo" (39.0040, -3.9629; Ciudad Real, Spain). Immediately after collection, they were segregated by sex and sent to the facilities of the Institute for Advanced Chemistry of Catalonia, where each sex was kept separately inside plastic cubic cages (Bugdorm ® , 30 × 30 × 30 cm; Entomopraxis, Barcelona, Spain) at 25 ± 1 • C, 55 ± 5% RH and 16:8 L:D. Insects were fed on fresh pistachio leaves (var. Kerman), and leaves were renewed every two days.
Samples were further analyzed in a Thermo Finnigan Trace 2000 gas chromatograph system coupled to a Trace MS quadrupole mass spectrometer (Thermo Fisher Scientific, Madrid, Spain). The injection port temperature was set at 270 • C, and samples were run in splitless mode (5 min) in a non-polar TR-5MS column (30 m × 0.25 mm I.D. × 0.25 µm; Thermo Fisher Scientific). The following temperature program was set up: an initial temperature of 50 • C held for 5 min, followed by an increase of 5 • C/min to 150 • C and, finally, an increase to 310 • C at 15 • C/min, with a hold time of 10 min. The MS system operated in electron impact mode (70 eV), and scan mode (40-500 amu), at 1.0 scan/s. Compound identification was achieved by comparison of the experimental mass spectrum with those of the synthetic standard and a commercial mass spectral library (NIST Registry of Mass Spectral Data, 2005), and by comparison of the KI values of both the male-released compound and the synthetic standard. For determining the KI values, first, a 50 ng/µL hexane dilution of the n-alkane mixture was prepared and, subsequently, 1 µL of this dilution was injected under the same conditions as those set for analyzing the HS-SPME samples.

Electroantennographic (EAG) Response
The olfactory response of L. lusitanica males (n = 8-10) and females (n = 8-10) to increasing quantities of 2-isobutyl-3-methoxypyrazine (1, 10, and 100 µg) was determined using electrophysiological recordings from severed antennae. Briefly, one antenna of a coldanesthetized adult was excised with the aid of a microscapel, and once excised, last two antennomeres were removed. The antenna was then fixed to a forked microelectrode holder (Syntech, Kirchzarten, Germany) with a drop of conductive gel (Spectra 360, Parker Lab. Inc., Hellendoorn, The Netherlands), placing the distal part of the antenna on the recording microelectrode, and the proximal part on the reference microelectrode. The holder was connected to an EAG Combi-Probe (Syntech, Kirchzarten, Germany) connected to a MP-5 micromanipulator (Syntech). Stimuli were delivered to the insect antennae by applying pure air puffs (ca. 300 mL/min) for 100 ms with a disposable glass Pasteur pipette (150 mm long) that contained a filter paper disc (2.5 cm diameter, Whatman ® , Merck-Sigma Aldrich, Madrid, Spain) loaded with 10 µL of the corresponding hexane dilution of 2-isobutyl-3methoxypyrazine (0.1, 1.0, or 10 µg/µL). Two puffs for each amount of compound were applied to each antennal preparation in increasing order of magnitude, with an interval of 60 s between puffs. Control puffs with 10 µL of hexane were intercalated between two consecutive 2-isobutyl-3-methoxypyrazine stimuli to determine the baseline depolarization of the antenna. A continuous humidified pure air flow (ca. 650 mL/min) passed over the antenna through the open end of a T-shaped glass tube (7 cm long × 5 mm diameter) positioned 1 cm over the sample, in order to prolong the life of the antennal preparation. The net EAG response evoked by each amount of 2-isobutyl-3-methoxypyrazine was calculated by subtracting the mean EAG amplitudes of the hexane puffs before and after the test compound. The EAG signals were amplified (10×) with the EAG Combi-Probe, filtered (DC to 1 kHz) with the aid of an IDAC-2 interface (Syntech, Kirchzarten, Germany), digitized on a PC and further analyzed with EAG Pro software (version 2.0, Syntech, Kirchzarten, Germany).

Behavioral Bioassays
A vertically placed dual-choice glass olfactometer (main arm 10 cm long × 18 mm I.D., arms 8 cm long × 18 mm I.D., angle between arms 90 • ) was used to determine the walking preference of L. lusitanica males (n = 31-40) and females (n = 36-49) in response to 2-isobutyl-3-methoxypyrazine (0.1, 1, and 10 µg). A Whatman ® filter paper disc loaded with 10 µL of the corresponding hexane dilution of 2-isobutyl-3-methoxypyrazine was placed in one of the olfactometer arms, whereas the control arm held a filter paper loaded with 10 µL of hexane, as a control. Filter papers were replaced every five insects, and the position of the arms were also switched to avoid any directionality. An incoming Insects 2023, 14, 107 4 of 10 charcoal-filtered air flow at 350 mL/min was set for both arms. The whole system was surrounded by a white filter paper screen (45 cm height) to avoid the interference of visual stimuli [18]. Homogenous illumination (light intensity ca. 500 lux) was provided with a bulb placed 30 cm above the junction of the olfactometer. A Y-shaped copper wire was introduced to facilitate insect movement along the olfactometer. Prior to the beginning of each trial, beetles were individually isolated in polystyrene cell culture dishes (Corning Inc, NY, USA), and left for 1 h to acclimate to room conditions. A positive response was considered if the insect entered any arm, walked at least 2 cm beyond the junction and remained there or continued walking until the end of the arm. Beetles that did not make a choice were designated as non-responders and, therefore, discarded for further statistical analysis. All the behavioral assays were conducted from 10:00 to 18:00 at room temperature.

Statistical Analysis
Prior to any statistical analysis, the EAG net amplitudes in response to 2-isobutyl-3methoxypyrazine were subjected to the Shapiro-Wilk and Levene tests and, when necessary, data were log-transformed to fulfill the assumptions of normality and/or homogeneity of variance. Differences in absolute EAG responses within a sex were analyzed using one-way analysis of variance (ANOVA). A subsequent Tukey's HSD post hoc test was applied for pairwise comparisons when ANOVA was significant. Differences between sexes in response to a concrete amount of stimulus were analyzed with Student's t-test. The walking response in the double-choice olfactometer was subjected to a chi-square goodness-of-fit test to address if the arm preference displayed by each sex differed from a 50:50 distribution. All the statistical tests were performed using SPSS Statistics 17.0 software (SPSS, Chicago, IL, USA), at a significance level of α = 0.05.

HS-SPME Collections
All the volatile collections from males (n = 10) revealed the presence of a sex-specific compound (KI = 1185), whereas no traces were detected in any of the samples from females (n = 10) (Figure 1a). The base peaks at m/z 124, resulting from a McLafferty rearrangement and the loss of C 3 H 6 , at m/z 151, produced by the loss of a methyl group from the isobutyl chain, and a possible molecular ion at m/z 166 tentatively suggested its identification as 2-isobutyl-3-methoxypyrazine [19]. Further comparison of the mass spectrum with those of the commercial library and the synthetic standard (KI = 1185) corroborated the identification of the eluting compound as 2-isobutyl-3-methoxypyrazine (Figure 1b).
In this sense, pheromone-mediated aggregation is a common behavior in insects, including leaf beetles (Coleoptera: Chrysomelidae) [34], in which chemical cues clearly play a pivotal, although not exclusive, role. Indeed, the elucidation of aggregation pheromones has been widely documented in chrysomelid species, with males as the sex responsible for their emission [35][36][37][38][39][40][41][42][43][44]. Here, we present the first empirical evidence of IBMP as a malespecific volatile compound that may be mediating aggregation in the leaf beetle L. lusitanica. This hypothesis is partially supported by our findings, with males being the sex responsible for the IBMP emission, as reported in other leaf beetle species, and both sexes showing a significant preference towards the compound. To the best of our knowledge, no pyrazine has been identified as a pheromone in leaf beetles so far. Indeed, most of the research on the pyrazine motif as pheromones has been conducted in ants, in which they act as alarm or trial pheromones [45][46][47], in true fruit flies (Diptera: Tephritidae) [48][49][50], in thynnine wasps [20] and in ladybugs [32,33,51]. As stated above, in some coccinellid species, an aggregative effect is induced by 2-alkyl-methoxypyrazines in diapausing individuals, aside from their roles as allomones. Al Abassi and coworkers reported that IPMP is attractive for both sexes of Coccinella septempunctata (L.) (Coleoptera: Coccinellidae) under laboratory conditions, inducing an attractive and arrestant effect attributable to the effect of an aggregation pheromone [32]. Similarly, IBMP alone or mixed with IPMP results in attraction for diapausing individuals in Adalia bipunctata (L.) (Coleoptera: Coccinellidae) [51]. In other ladybug species, such as Harmonia axyridis Pallas and Hippodamia convergens Guérin-Méneville (Coleoptera: Coccinellidae), IPMP, IBMP and SBMP have been identified [52] and demonstrated to be behaviorally active. In the case of H. convergens adults, SBMP, and especially IBMP and the ternary blend at its natural ratio, induce significant aggregative effects in laboratory and field assays, whereas high amounts of IPMP and SBMP were shown to be repellant [33]. Likewise, an aversive behavior in L. lusitanica males was evident when they were confronted with the highest amount of IBMP in olfactometer trials. Given the dual activity of 2-alkyl-methoxypyrazines in ladybugs, it seems probable that IBMP may play a similar role in L. lusitanica, not only resulting in attraction for both sexes, but also conferring a defense mechanism against predation.
According to field observations, L. lusitanica aggregates with a high number of individuals (more than 50) are found only in a few pistachio trees, while most of the trees harbor smaller numbers (less than 15) [17]. In a similar vein, the response of males and females of Aphthona nigriscutis Foudras (Coleoptera: Chrysomelidae) to aggregation cues decreases according to the density of conspecifics on the plant [38]. In the latter, it is not acknowledged if this density-dependent response may be conditioned by deterrent plant volatile organic compounds released upon feeding by conspecifics [53][54][55]. For example, Diorhabda carinulata Desbrochers (Coleoptera: Chrysomelidae) avoids previously defoliated saltcedar plants, and this avoidance has been correlated with the release of 4-oxo-(E)-2-hexenal from the host, inducing a repellent effect on reproductive males and females [53]. Nonetheless, since L. lusitanica colonizes healthy and non-consumed pistachio leaves from young trees, this hypothesis should be a priori discarded. Alternatively, we suggest that chemical cues from pistachio trees may be signaling the suitability of the host to some extent, partially explaining, therefore, the patchy spatial pattern of aggregates of variable numbers of individuals across the crop. Indeed, plant volatiles are demonstrated to be relevant in the aggregation processes of Chrysomelidae, either by luring in the pioneer individuals [43,56] or by enhancing/synergizing the effect of the aggregation pheromone [38,[57][58][59][60], as it occurs in other coleopteran families [61,62]. Furthermore, being in contact with the host plant and/or feeding seem to be sine qua non conditions for pheromone release in leaf beetle species [41][42][43][44]56,63]. Examples highlighting this phenomenon are found in Acalymma vittatum (F.), whose feeding males are more attractive to conspecifics than non-feeding males [43], in Phyllotreta spp. [41,44] and in Oulema melanopus (L.), in which the release of aggregation pheromones is closely related to males feeding on the host plant [42]. In our case, IBMP was detected from males deprived of pistachio leaves during the volatile collection, although they were not subjected to starvation prior to the sampling. Thus, it remains unanswered whether the presence of plant volatiles and/or pistachio leaf consumption are crucial for the release of IBMP.
In summary, we have identified a male-specific compound that results in the attraction of both sexes under laboratory conditions. Future field research is ongoing to gain a broader understanding of the role of the compound in the chemical ecology of L. lusitanica, in order to determine its potential activity under natural conditions. Last, but not least, a thorough understanding of their population dynamics, and whether the production and release of 2-isobutyl-3-methoxypyrazine remain constant during the whole life cycle, would also be paramount for deciphering the biological implications of the compound. Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.
Data Availability Statement: All the data generated from the current work are available upon reasonable request to the corresponding authors.