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Article

Volatile Infochemicals from Rhyzopertha dominica Larvae and Larval Feces Involved in Theocolax elegans Host Habitat Location

Department of Agriculture, University Mediterranea of Reggio Calabria, Loc. Feo di Vito, 89122 Reggio Calabria (RC), Italy
*
Authors to whom correspondence should be addressed.
Insects 2021, 12(2), 142; https://doi.org/10.3390/insects12020142
Submission received: 18 December 2020 / Revised: 22 January 2021 / Accepted: 3 February 2021 / Published: 7 February 2021
(This article belongs to the Special Issue Post-Harvest Insect Chemical and Behavioral Ecology)

Abstract

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Simple Summary

Food protection is a key issue to guarantee food security. One of the major criticisms is related to insect pests, which can severely damage stored products. Control of stored product pests widely relies on synthetic pesticides, which are potentially harmful to human health and the environment. In this context, the application of chemicals during post-harvest should be limited, and natural enemies, like parasitoid wasps, might be useful for biologically based pest management programs. The effectiveness of this approach under field conditions is still uncertain, and more information about parasitoid biology and behavior can be valuable to improve mass rearing and control strategies. This study investigates the host habitat location behavior of Theocolax elegans, a generalist parasitoid attacking several stored product pests, including Rhyzopertha dominica, a key pest species of stored grains. Bioassays demonstrated that the parasitoid females were not attracted by intact kernels; indeed, the parasitoid females were strongly attracted by infested wheat and by the host feces, locating the suitable hosts through the characteristic volatile infochemicals emitted by these substrates. Results from the present research are encouraging and suggest that biological control agents might be used to reduce the amount of synthetic insecticides.

Abstract

The development of biologically based approaches for stored product pest control is needed to reduce chemical inputs. Bioassays were performed to investigate host habitat location in the trophic interaction durum wheat/Rhyzopertha dominica/Theocolax elegans. GC-MS analyses were carried out to identify some chemical compounds produced by the host-related substrates. Choice and no-choice experiments demonstrated that female parasitoids were poorly attracted to intact kernels with respect to the infested substrates. Furthermore, T. elegans females performed longer residence time on infested wheat, and they generally displayed a short-term like fidelity for this cue, remaining on it during the whole observation. Infested wheat emitted one chemical (fenchone), which is possibly linked to host larvae presence, while the feces produced by host larvae emitted some other characteristic compounds. Results demonstrated that the presence of host larvae is a key factor for T. elegans host habitat location, considering that the attractiveness of the undamaged wheat is irrelevant. Furthermore, parasitoid females tended to stay on attractive cues, limiting the risk of contamination of other commodities. Biological control tools may be useful to improve the efficiency of pest management programs, but their application should be carefully evaluated.

Graphical Abstract

1. Introduction

The damage caused by insect pests during post-harvest significantly contributes to global food loss (almost 1.3 billion tons of food every year across the world) [1], influencing also food quality [2]. Yearly, over 2 billion tons of grain are harvested and stored for food and feed, but around 30% of these stored products are damaged by insect and mite pests despite the massive use of synthetic pesticides [3]. Moreover, in the last two decades, resistance to specific chemicals has been recorded for more than 504 pest species, including many stored product insect pests [3,4], reducing the effectiveness of pesticide treatments. Thus, the development of alternative approaches for pest control is a key issue to address the increasing market demand for pesticide and insect-free food, as well as to face the shortage of food commodities in many countries worldwide [5,6,7].
Among alternative approaches, biological control using natural enemies has been neglected due to legal impairments and contamination concerns. For these reasons, in many countries, the release of parasitoids and/or predators inside warehouses is not carried out, despite being legally allowed in the United States [8] and some countries of Central Europe [9]. Food regulations usually set certain levels of insect fragments in food that cannot be exceeded regardless of their origin (i.e., pest insects or natural enemies) detected by filth tests [3]. In this scenario, the intentional release of insects inside food factories discourages the storehouses because of the elevated risk of contaminants. Furthermore, to date, commercial suppliers producing natural enemies for stored product pests are limited, and there is a lack of practical expertise from pest control operators. Further research on biological control agents for stored product protection is needed to investigate their safety and efficacy, as well as to increase the knowledge about their biology and the mechanisms involved in pest/parasitoid interaction, which can be useful for their mass rearing.
Parasitoids attacking stored product pests mainly belong to the hymenopteran families Pteromalidae, Ichneumonidae, Braconidae and Bethylidae [9,10,11]. Theocolax elegans (Westwood) (Hymenoptera: Pteromalidae) is a cosmopolitan solitary ectoparasitoid of several stored product pests, including the coleopteran species Rhyzopertha dominica F. (Coleoptera: Bostrychidae), Stegobium paniceum L. (Coleoptera: Anobiidae), Callosobruchus spp. (Coleoptera: Chrysomelidae), Sitophilus spp. (Coleoptera: Curculionidae), and the grain moth Sitotroga cerealella Olivier (Lepidoptera: Gelechiidae) [12]. As a solitary parasitoid, only one T. elegans larva can survive at the expense of a single host larva [13]. This parasitoid species preferably parasitizes 3rd and 4th instar larvae of cereal primary feeders (i.e., pests able to damage intact kernels, whose larvae develop inside the caryopses), because T. elegans females do not oviposit on wandering larvae [14,15,16]. This parasitoid could reduce the population of Sitophilus zeamais Motschulsky, Sitophilus oryzae L. and R. dominica from 50 to 99% [13,17,18,19], while could not suppress populations of Prostephanus truncatus (Horn) (Coleoptera: Bostrychidae), a species closely related to R. dominica [20]. In contrast to other parasitoid species, T. elegans shows high effectiveness at medium-low temperature; the optimal developing temperature is around 25 °C and its fecundity is significantly reduced at 32 °C [21]. This characteristic is crucial for the use of this parasitoid species under field conditions. Furthermore, the synergy of T. elegans and Anisopteromalus calandrae Howard (Hymenoptera: Pteromalidae) to control Sitophilus spp. was investigated, and the results highlighted that A. calandrae was generally more effective, while T. elegans performed better at lower temperatures [17,18].
Host location is a key phase for parasitoids, and parasitoids of stored product pests can rely on a limited number of stimuli to locate their hosts and host habitats. Visual cues play a restricted role because visual stimuli are quite limited in warehouses and industries. Host-finding is mainly mediated by olfactory cues at long range and probably by vibrational and olfactory cues at short range [22]. Some studies aimed to investigate the role of cereal volatiles and host volatiles on the behaviour of T. elegans [23,24,25], however, it is still unclear which molecules may be involved in host selection and detection. In this study, the olfactory cues involved in the tri-trophic interaction durum wheat/R. dominica/T. elegans were investigated in choice and no-choice experiments. Furthermore, the chemical characterization of the Volatile Organic Compounds (VOCs) sampled from the host substrates was provided.

2. Materials and Methods

2.1. Plant Material and Insect Colonies

Pesticide-free durum wheat (cv. Antalis) for insect rearing and Gas Chromatography-Mass Spectrometry (GC-MS) analyses was provided by Azienda Agricola Bognanno, Villarosa, EN, Italy (GPS coordinates: 37°35′47.0″ N, 14°10′09.8″ E). In order to ensure the absence of previous infestations, the grain was directly collected from the field on the day of harvesting; the grains were sieved using a vibrating sieve to eliminate impurities and then refrigerated at −20 °C for 48 h to avoid any possible future infestation. Samples of the collected grains were additionally subjected to different methods of analysis (floating, visual observation, and incubation) that confirmed the total absence of pests. The wheat was stored at the Department of Agriculture of the University Mediterranea of Reggio Calabria inside a climatic chamber at 10 °C until the beginning of the experiments.
Insect colonies were reared under controlled conditions (28 ± 1 °C, 50 ± 5% R.H.) at the Department of Agriculture of the University Mediterranea of Reggio Calabria. The parasitoid T. elegans and its host R. dominica were originally collected from a local milling industry (Melito Porto Salvo, Italy; GPS coordinates: 37°55′27.8″ N, 15°45′35.5″ E).
For parasitoid rearing, 300 unsexed Sitophilus zeamais Motschulsky (Coleoptera: Curcolionidae) adults were placed inside a glass jar (1 L) with 500 g of rice (var. Ribe), to attain oviposition. After 1 week the grain was sieved to remove the adults and incubated for 5 weeks to ensure the development of S. zeamais larvae. Newly emerged T. elegans adults were transferred on the S. zeamais-infested rice. Newly emerged parasitoids were daily collected and promptly moved to fresh rearing media or used for the trials. Parasitoids were reared on a different host/plant complex to ensure that females had no previous contact with wheat grain or R. dominica and, therefore, could be considered naive with respect to the tested substrates [26].
To obtain the media for volatile analyses, 300 R. dominica adults were placed inside a glass jar (1 L) with 500 g of wheat, to attain oviposition. After 1 week the grain was sieved to remove the insects and incubated for 5 weeks to ensure the development of R. dominica larvae. The obtained substrate was used for VOCs analysis from infested wheat and larval feces.

2.2. General Methods for Bioassays

Parasitoid insects used for the behavioral assays were collected within one hour from emergence and sexed under a stereomicroscope. Female and male parasitoids (approximately 100 individuals; sex ratio 1:1) were then released inside a clean glass jar, provided with moistened cotton wicks, to ensure mating. After 48 h, T. elegans females (2 days old) were singly placed inside glass vials closed with a moistened cotton cap and tested within 1–2 h.
All the behavioral assays were carried out at 25 ± 1 °C and 50 ± 5% R.H. During the bioassays, different substrates were offered to the parasitoid females in an arena made from a glass Petri dish (5.5 cm diam.) with a glass lid [27]. Parasitoid females were allowed to enter the arena by a central hole in the lid. The bioassay arena was placed inside a white chamber illuminated by artificial LED light, to exclude any possible visual cues influencing insect orientation. The observation for the single parasitoid lasted 5 min from the release [28]. After every observation, the substrates used as attractive stimuli were renewed and after 5 observations the arena was replaced by a clean one and the position of the cues was rotated. Thirty active-searching parasitoids were used for every trial. Females which did not show any searching activity (i.e., walking and drumming) after 4 min from the release were annotated (NS = no-searching), but discarded from further analyses.

2.3. No-Choice and Choice Experiments

Four different stimuli were used for the bioassays: (i) undamaged intact wheat kernels (U); (ii) infested wheat kernels (I), containing 5-week-old R. dominica larvae and their feces; (iii) undamaged intact wheat kernels mixed with R. dominica larval feces (U+F); (iv) R. dominica larval feces (F). The kernels were previously checked for larval presence/absence under a stereomicroscope. For the trials, 500 mg of wheat kernels (around 10 kernels) were used for each stimulus. When the larval feces were included alone or mixed to wheat kernels, to reproduce the regular R. dominica larval excretion, 50 mg of material was used [29].
In no-choice experiments, a single stimulus was placed on one side of the arena. In choice bioassays, 2 different stimuli were placed on the opposite sides of the testing arena. The following comparisons were tested in choice trials:
  • Undamaged vs. Infested kernels
  • Undamaged vs. Undamaged kernels + Feces
  • Infested kernels vs. Undamaged kernels + Feces
  • Infested kernels vs. Feces
During the observations, the residence times (i.e., actively performing searching behavior [30]) spent by the choosing (C) females in close proximity (5 mm) or on the given substrates were recorded. Females actively searching which did not spend time in close proximity to the food sources were also recorded and labelled as no-choosing (NC) insects. The insect should spend at least 15 consecutive sec searching on the stimulus for the residence time to be recorded. Furthermore, for choice tests also the first choice (i.e., the first stimulus approached by the T. elegans female) was recorded.

2.4. Identification of Volatile Organic Compounds (VOCs)

VOCs emitted by undamaged and infested wheat and by larval feces were sampled in HS-SPME (Head Space- Solid Phase Micro-Extraction) technique by a polydimethylsiloxane (PDMS, 100 μm) Supelco® fiber (Bellefonte, PA, USA). Wheat kernels (5 g) and feces (200 mg) were incubated at 27 ± 1 °C inside airtight glass vials (20 mL and 3 mL, respectively). SPME sampling was performed using the same new fiber, preconditioned according to the manufacturer’s instructions. After the incubation period, the fiber was inserted and exposed to headspace for 1 h and then desorbed for 5 min in the GC-MS injector. For every substrate, 4 replicates were provided. The sampling and desorption conditions were identical for all the samples and blanks were run before the first SPME extraction and were also randomly repeated during the injection sequences. To evaluate quantitative differences, peak areas of the same identified chemical among the different wheat samples were compared.
GC-MS analyses were performed with a Thermo Fisher TRACE 1300 gas chromatograph equipped with a MEGA-5 capillary column (30 m × 0.25 mm; coating thickness = 0.25 μm, with 10 m of pre-column) and a Thermo Fisher ISQ LT ion trap mass detector (emission current: 10 microamps; count threshold: 1 count; multiplier offset: 0 volts; scan time:1.00 s; prescan ionization time: 100 microseconds; scan mass range: 30–300 m/z; ionization mode: EI). The analytical conditions used were injector and transfer line temperature at 250 and 240 °C, respectively; oven temperature programmed from 60 to 240 °C at 3 °C min−1; carrier gas, helium at 1 mL min−1; splitless injection. The identification of VOCs was made comparing the mass spectra, as well as the linear retention indices (LRI), calculated using a series of n-hydrocarbons (C7–C30 saturated alkanes standard mixture, Supelco®, Bellefonte, PA, USA) [31]), and the retention times (RT) with those of commercial libraries (NIST 98 and ADAMS) and those of a library made from pure substances components of known oils and MS literature data [32,33,34,35,36].

2.5. Data Analysis

Binary data were analyzed using Chi-square test with one degree of freedom, while relative proportions of NC females among no-choice experiments were analyzed using Chi-square test for contingency table (3 × 2). Residence times were tested for ANOVA assumptions, normality (Shapiro–Wilk test) and homoscedasticity (Levene’s test); since these assumptions were not met also after data transformation, the data from no-choice trials were compared using the non-parametric Kruskal–Wallis H test followed by Dunn’s post hoc test for multiple comparison, while residence times from each comparison in choice bioassays were analyzed using Mann–Whitney U test.
Relative peak areas from every VOC identified in undamaged and infested wheat kernels were Log-transformed, tested for normality (Shapiro–Wilk test) and homoscedasticity (Levene’s test) and analyzed with one-way ANOVA using “infestation” as fixed factor.

3. Results

3.1. Parasitoid Preferences for Different Host-Substrates

In no-choice trials, parasitoid females were attracted to infested wheat with respect to all other tested stimuli (Table 1). A significantly higher number of females actively host-searched in close proximity to this substrate, while very few T. elegans females contacted undamaged kernels (χ2 = 30.18; df = 3; p < 0.0001). Furthermore, the tested cues evoked significantly different residence times on T. elegans females (H3,58 = 9.72; p = 0.021), which spent significantly more time on infested wheat kernels than undamaged ones or feces, while no statistical differences were found towards residence times on undamaged grains supplemented with larval feces.
The behavioral responses of parasitoid females demonstrated that T. elegans possessed an innate attraction for some substrates, because they started searching first on the most attractive stimuli (Figure 1). Considering the first choice (i.e., the first stimulus approached by the T. elegans female), undamaged wheat was significantly less attractive for parasitoid females than grains infested by R. dominica2 = 16.13; df = 2; p = 0.0003) or undamaged kernels supplemented with host feces (χ2 = 19.20; df = 2; p < 0.0001). Furthermore, undamaged wheat added with larval feces had the same immediate attractiveness as infested wheat (χ2 = 2.13; df = 2; p = 0.34), suggesting the crucial role of feces on the host habitat location process. This hypothesis was also supported by the results of experiments with infested kernels vs. feces. T. elegans showed no differences in first choices for these two host substrates (χ2 = 1.20; df = 2; p = 0.55).
In choice experiments, no significant differences were observed among the residence times when considering all the choosing insects (Total values in Table 2). However, there were differences in the number of insects actively searching on the cues; fewer female parasitoids searched on the intact wheat in comparison with the infested one (χ2 = 14.23; df = 2; p = 0.0008) or with the kernels supplemented with larval feces (χ2 = 21.13; df = 2; p < 0.0001). Conversely, the number of T. elegans females spending time on infested wheat was not significant different from those on intact wheat supplemented with feces (χ2 = 1.45; df = 2; p = 0.484) or on larval feces alone (χ2 = 2.00; df = 2; p = 0.367).
Evaluating the females’ selection in choice experiments according to their first choice, generally, parasitoids spent significantly more time on the substrate that was first contacted (Table 2). T. elegans females, first oriented to infested kernels, spent significant more time actively searching on this cue than on all the other stimuli (undamaged grain: U1,26 = 4.21; p = 0.040; undamaged grain supplemented with feces: U1,16 = 3.97; p = 0.046; feces alone: U1,16 = 5.14; p = 0.023). Similarly, females choosing first undamaged grain supplemented with feces remained on this stimulus more than on the less attractive undamaged kernels (U1,26 = 3.79; p = 0.045). Longer residence times were also displayed on feces alone with respect to infested wheat, when the females were attracted by the former (U1,12 = 4.33; p = 0.042). Considerably, T. elegans females did not show any short-term fidelity for intact wheat; females choosing first intact wheat did not remain on this cue during the whole duration of trials, but they spent the same time also actively searching on the other cue provided in the arena (Table 2).
The recorded residence times suggest that the parasitoid females generally stayed on innately attractive substrates and avoided searching for other suitable host patches. This kind of short-term fidelity is supported by the number of parasitoids actively searching on the cues in choice experiments. Females choosing first infested kernels tended to stay on this substrate when contrasted with undamaged grains (χ2 = 20.57; df = 2; p < 0.0001) or only feces (χ2 = 18.00; df = 2; p = 0.0001). Conversely, there were no significant difference between the number of searching parasitoids on infested and undamaged + feces grains in choice trials, suggesting that these two substrates were equivalent (First choice = Infested: χ2 = 0.89; df = 2; p = 0.64; Undamaged + Feces: χ2 = 5.54; df = 2; p = 0.06). Notably, substrate fidelity was noted also for feces alone in comparison with infested wheat (χ2 = 7.14; df = 2; p = 0.03). Lastly, T. elegans females attracted to intact kernels tended to explore also the other given cue offered in the arena (intact vs. infested wheat: χ2 = 0.67; df = 2; p = 0.71; intact vs. undamaged + feces wheat: χ2 = 0.20; df = 2; p = 0.90).

3.2. VOCs Identification from Host-Substrates

Fourteen volatile compounds emitted by the various tested substrates were identified by GC-MS analysis following the method by Giunti et al. [37] (Table 3). Specifically, 10 volatile compounds were detected from undamaged wheat samples, while 12 VOCs infested wheat ones. The prominent volatile compounds for both grains were the alkane n-decane and the alcohol 1-tetradecanol. Overall, the majority of the identified VOCs were hydrocarbons, alcohols and aldehydes.
The emissions of undamaged and infested wheat significantly differed with the emissions of four molecules. Only one compound was exclusively found in undamaged wheat, the aldehyde dodecanal. In contrast, three VOCs were emitted only by the infested kernels: the oxygenated monoterpene fenchone, the ester methyl-decanoate and the alkene 1-pentadecene. On the other hand, larval feces produced a small number of volatiles (eight compounds), all of which were also present in the volatile profile of the infested wheat. Among the three VOCs found in infested wheat, methyl-decanoate and 1-pentadecene were also detected in feces’ profiles.

4. Discussion

Theocolax elegans females can locate potential host habitats using olfactory cues directly produced by their hosts, as well as emitted by pest-damaged substrates. The emission of HIPVs attractive for parasitoid insects has been widely investigated for crop plants [38,39], whereas the ability of grains to produce kairomones has been underestimated so far. Nevertheless, the occurrence of characteristic molecules linked to pest infestation has been demonstrated for the pteromalid parasitoid Lariophagus distinguendus Förster (Hymenoptera: Pteromalidae) [40,41,42,43], a generalist solitary ectoparasitoid of immature stages of at least 11 stored product pests. Concerning T. elegans, grain volatiles were found to be perceived and attractive for both sexes [22,23]. The ability of T. elegans females to discriminate between infested and intact kernels has been firstly investigated by Tang [24,25], who highlighted that host-related substances (i.e., larval saliva and frass) can play a role in parasitoid preferences. Furthermore, experienced T. elegance females could discriminate between S. zeamais-infested rice kernels and artificially damaged ones, whereas naïve females could not [24,25]. These studies provided no information about the VOC emitted by the tested rice substrates. However, the presence of specific molecules emitted by rice kernels in response to pest infestation has been investigated by recent research on the ecological interactions among three stored product pests (i.e., S. zeamais, Tribolium confusum du Val (Coleoptera: Tenebrionidae) and Cryptolestes ferrugineus (Stephens) (Coleoptera: Laemophloeidae)) [44].
The present study investigated the innate attractiveness of R. dominica-infested wheat and R. dominca larval feces toward T. elegans. Infested wheat grains can elicit longer residence times in choice and no-choice experiments, also evoking a kind of fidelity (i.e., insects remain on the first contacted substrate during the whole observation) for this substrate. Female parasitoids tend to remain on the infested wheat rather than to move and explore the other host substrates provided in the trials. This result enlightens the strong attractiveness of infested wheat and the key role of the host presence to elicit arrestment and standing on the cue. Volatile profiles from wheat infested by R. dominica larvae and intact wheat demonstrated that the emissions of four compounds were altered by host infestation; one chemical was produced in a higher amount by undamaged kernels, while three VOCs were associated to host larvae presence. However, only the oxygenated monoterpene fenchone was emitted by infested wheat but was absent in the volatile profile from larval feces. The absence of these molecules in R. dominica frass suggests that this molecule is directly emitted by infested grain. The bioactivity of fenchone has been proven also for the pteromalid parasitoid Roptrocerus xylophagorum (Ratzeburg) (Hymenoptera: Pteromalidae); this compound was associated with host presence (Dendroctonus frontalis Zimmermann and Ips grandicollis Eichhoff (Coleoptera: Scolytidae)) and could attract both males and females [45].
Larval feces enhance host habitat location by T. elegans females, increasing the arrestment duration also on undamaged grains. Olfactory cues from host feces can be exploited by several parasitoid species during their host-searching activity [46,47,48,49,50]. As an example, feces produced by several stored product pests can be attractive for L. distinguendus [29,41,51]. Fecal VOCs included some volatiles present also in undamaged wheat, suggesting that larval diet can influence the composition of the fecal excretions. However, the compounds methyl decanoate and 1-pentadecene were found only in infested grain profiles and feces, thus strictly correlating these compounds to host activity. 1-pentadecene is a known component of the fecal odor of T. confusum, which can elicit strong EAG responses and attraction toward T. confusum males and females [52], as well as toward the ectoparasitoid Holepyris sylvanidis (Brèthes) (Hymenoptera, Bethylidae) [53]. In contrast, methyl decanoate has never been detected before in the volatile profile of R. dominica feces, although this substrate is generally rich in linear and ramified hydrocarbons [29]. Steidle et al. [29] found a considerable amount of dominicalure 1 and 2, the species-specific male-released aggregation pheromones of R. dominica, in the R. dominica larval frass; conversely, these compounds were not detected in the present study. However, according to the authors, the conspicuous presence of adult pheromones in larval feces was due to the rearing conditions, because adult beetles were never completely removed from the larval cultures used for the experiments.
From an applied point of view, results on the limited attraction of undamaged wheat grain were encouraging because the presence of hosts is a key factor for host habitat location. Biological control for stored product pests is quite limited, either for operative criticisms, but also because of reluctance and concerns about the introduction of organisms in food thereby potentially increasing insect residues. Nevertheless, Flinn et al. [13,21] demonstrated that the augmentative release of T. elegans in wheat bins to control R. dominica infestation led to a significant reduction of insect fragments at the end of the storage period. The low number of T. elegans females approaching intact kernels suggests that parasitoids would concentrate on host infested materials and would avoid unsuitable substrates, lowering the risk of contamination of other products or raw materials.
The release of T. elegans can be used in combination with other biorational tools, in order to decrease the application of synthetic pesticides and to improve the whole efficiency of integrated pest management (IPM) programs in the food industry. Indeed, fumigation with carbon dioxide (about 60%, for 22 days) of bag stacks, containing rye and wheat, could effectively suppress the R. dominica adult population, while T. elegans parasitoids could survive as pupae, granting control of the survived host larvae [54]. Biological control agents, thus, can be combined with other low-impact approaches to improve the efficacy, as well as the sustainability, of control programs for stored product pests damaging food during post-harvest storage. Furthermore, the identification of host-related semiochemicals could be useful to improve the monitoring of parasitoid population density in field conditions [55] and may be used to increase the efficacy of parasitisation rates [38,42].
Further research is required to evaluate through electroantennographic assays whether the identified compounds can be perceived by parasitoids, the bioactivity of these VOCs and the impact of females’ experience on host habitat location. More information about the role of visual, tactile and vibrational stimuli on host and host habitat location would be necessary to better understand T. elegans behavior. Therefore, deeper knowledge about chemically mediated host/parasitoid interactions is essential to design appropriate and effective IPM programs, which can include biological agents to increase the eco-friendly methods to control stored product pests.

5. Conclusions

Overall, this research investigated for the first time the host habitat location behavior of T. elegans females on the complex R. dominica-durum wheat, highlighting the key role of host feces for parasitoid host habitat location. Results from choice and no-choice trials proved that cues from infested grain are more attractive for naïve female parasitoids with respect to stimuli from undamaged kernels. Furthermore, the infested host substrate elicited a sort of fidelity in T. elegans females attracted to R. dominica-infested wheat. Conversely, fidelity was not reported for undamaged wheat, suggesting that parasitoids did not spend much time searching for host larvae on unsuitable substrates.

Author Contributions

Conceptualization, G.G. and O.C.; methodology, G.G.; validation, G.G. and F.L.; formal analysis, G.G. and O.C.; investigation, G.G. and P.C.; resources, F.L. and V.P.; writing—original draft preparation, G.G. and O.C.; writing—review and editing, P.C., F.L. and V.P.; project administration, O.C.; funding acquisition, V.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding. G.G. was founded by POR CALABRIA FESR-FSE 2014-2020_Biocompostaggio degli scarti dell’industria agroalimentare mediata da insetti: sviluppo di un processo innovativo di bioconversione e valorizzazione (Grant ID: 4/2020/AGRARIA). Funders had no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Institutional Review Board Statement

Ethics approval was not required for this study.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data that support the findings of this study are available from the corresponding authors [G.G. and O.C.] upon reasonable request.

Acknowledgments

The authors would like to thank F. Araniti for his technical assistance.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. First choice of T. elegans females in choice experiments between paired substrates: I = R. dominica-Infested wheat; U = Undamaged wheat; U + F = Undamaged wheat + R. dominica larval feces; F = R. dominica larval feces. Asterisks indicate statistical differences (χ2 test, p < 0.05); n.s. = not significant. NS = no-searching female parassitoids.
Figure 1. First choice of T. elegans females in choice experiments between paired substrates: I = R. dominica-Infested wheat; U = Undamaged wheat; U + F = Undamaged wheat + R. dominica larval feces; F = R. dominica larval feces. Asterisks indicate statistical differences (χ2 test, p < 0.05); n.s. = not significant. NS = no-searching female parassitoids.
Insects 12 00142 g001
Table 1. Resident times (Mean ± SE) of T. elegans females in no-choice trials. Capital letters indicate significant differences among the numbers of choosing females (χ2 test, p < 0.05). Letters indicate significant differences among the times spent on the substrates (Kruskal–Wallis H test; p < 0.05).
Table 1. Resident times (Mean ± SE) of T. elegans females in no-choice trials. Capital letters indicate significant differences among the numbers of choosing females (χ2 test, p < 0.05). Letters indicate significant differences among the times spent on the substrates (Kruskal–Wallis H test; p < 0.05).
SubstratesNS 1 Females
(N 4)
NC 2 Females
(N)
C 3 Females
(N)
Residence Time
(s)
Infested3426 A129.0 ± 15.0 a
Undamaged + Feces31416 B97.8 ± 20.0 ab
Feces21218 B73.9 ± 11.7 b
Undamaged5255 C40.6 ± 12.1 b
1 No-searching; 2 No-choosing; 3 Choosing; 4 Number.
Table 2. Residence times (Mean ± SE) of T. elegans females in choice trials with paired cues. Asterisks (*) indicate significant differences between the number of insects spending Table 2 test; p < 0.05) or between the residence times spent on the cues (Mann–Whitney U test; p < 0.05) within the same row.
Table 2. Residence times (Mean ± SE) of T. elegans females in choice trials with paired cues. Asterisks (*) indicate significant differences between the number of insects spending Table 2 test; p < 0.05) or between the residence times spent on the cues (Mann–Whitney U test; p < 0.05) within the same row.
TrialCue ACue BFirst ChoiceCue A
(N 1)
Cue B
(N)
Residence Time Cue A (s)Residence Time Cue B (s)
1InfestedUndamagedInfested262*170.0 ± 20.616.5 ± 1.5*
Undamaged24ns 2158.0 ± 26.0143.3 ± 51.3ns
Total286*169.1 ± 19.1101.0 ± 42.0ns
2UndamagedUndamaged + FecesUndamaged32ns121.0 ± 75.0103.5 ± 67.5ns
Undamaged + Feces027*0.0 ± 0.0162.7 ± 19.0*
Total329*121.0 ± 75.0158.7 ± 18.2ns
3InfestedUndamaged + FecesInfested117ns163.8 ± 27.774.9 ± 16.3*
Undamaged + Feces719ns147.3 ± 15170.5 ± 21.9ns
Total1826ns157.4 ± 17.6144.7 ± 18.5ns
4InfestedFecesInfested180*179.4 ± 22.10.0 ± 0.0*
Feces212*73.0 ± 9.0213.8 ± 21.9*
Total2012ns168.8 ± 21.2213.8 ± 21.9ns
1 Number. 2 not significant.
Table 3. Volatile Organic Compunds (VOCs) identified by GC-MS analyses from different host substrates: undamaged and R. dominica-infested wheat, and R. dominica larval feces. Relative percentages of peak areas are mean ± standard error of three replicates. Asterisks (*) indicate significant differences between relative percentages of the same compound between undamaged and infested wheat (One-way ANOVA; p < 0.05).
Table 3. Volatile Organic Compunds (VOCs) identified by GC-MS analyses from different host substrates: undamaged and R. dominica-infested wheat, and R. dominica larval feces. Relative percentages of peak areas are mean ± standard error of three replicates. Asterisks (*) indicate significant differences between relative percentages of the same compound between undamaged and infested wheat (One-way ANOVA; p < 0.05).
CompoundLRI 1 CalculatedLRI LiteratureUndamaged (%)Infested (%)F 2p 3Feces (%)
Decane1000100033.58 ± 8.2111.84 ± 4.350.60.4734.67 ± 9.63
Limonene10381037tr 43.19 ± 3.140.610.46-
Fenchone10901087-4.78 ± 2.838.990.02 *-
Nonanal11011102-3.6 ± 2.982.990.13tr
1-Decanol127412741.19 ± 1.033.32 ± 1.093.920.15.88 ± 1.36
Tridecane129913002.2 ± 1.32-3.000.13-
Undecanal131013060.95 ± 0.661.63 ± 0.690.480.51tr
Methyl-decanoate13311326-3.43 ± 1.37066.36<0.001 *8.48 ± 2.29
Tetradecane13981400tr-1.000.36tr
Dodecanal141214095.9 ± 3.56-7.990.03 *-
1-Pentadecene14911491-1.67 ± 0.68.980.02 *0.45 ± 0.25
1-Hexadecene158515898.85 ± 8.650.38 ± 0.380.0010.98-
Tetradecanal161416116.07 ± 2.69tr1.110.33-
1-Tetradecanol1681167636.67 ± 17.9646.78 ± 10.611.530.2647 ± 14.34
Total 97.04 ± 2.5598.23 ± 1.69 96.78 ± 3.03
1 Linear Retention Index; 2 F value of one-way ANOVA; 3 Probability of one-way ANOVA; 4 traces.
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Giunti, G.; Campolo, O.; Caccamo, P.; Laudani, F.; Palmeri, V. Volatile Infochemicals from Rhyzopertha dominica Larvae and Larval Feces Involved in Theocolax elegans Host Habitat Location. Insects 2021, 12, 142. https://doi.org/10.3390/insects12020142

AMA Style

Giunti G, Campolo O, Caccamo P, Laudani F, Palmeri V. Volatile Infochemicals from Rhyzopertha dominica Larvae and Larval Feces Involved in Theocolax elegans Host Habitat Location. Insects. 2021; 12(2):142. https://doi.org/10.3390/insects12020142

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Giunti, Giulia, Orlando Campolo, Pasquale Caccamo, Francesca Laudani, and Vincenzo Palmeri. 2021. "Volatile Infochemicals from Rhyzopertha dominica Larvae and Larval Feces Involved in Theocolax elegans Host Habitat Location" Insects 12, no. 2: 142. https://doi.org/10.3390/insects12020142

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