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Cuticular lipid profiles of selected species of cyclocephaline beetles (Melolonthidae, Cyclocephalini)

Published online by Cambridge University Press:  25 January 2024

Geanne Karla N. Santos
Affiliation:
Secretaria Executiva de Meio Ambiente de Paulista (SEMA), Prefeitura Municipal do Paulista, Paulista, 53401-441, Brazil Department of Fundamental Chemistry, Centro de Ciências Exatas e da Natureza, Universidade Federal de Pernambuco, Recife, 50740-560, Brazil
Daniela Maria do Amaral F. Navarro
Affiliation:
Department of Fundamental Chemistry, Centro de Ciências Exatas e da Natureza, Universidade Federal de Pernambuco, Recife, 50740-560, Brazil
Artur Campos D. Maia*
Affiliation:
Department of Zoology, Centro de Biociências, Universidade Federal de Pernambuco, Recife PE, 50670-901, Brazil Laboratory of Sciences for the Environment, University of Corsica, UMR 6134 SPE, Ajaccio, France
*
Corresponding author: Artur Campos D. Maia; Email: [email protected]
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Abstract

Neotropical cyclocephaline beetles, a diverse group of flower-loving insects, significantly impact natural and agricultural ecosystems. In particular, the genus Cyclocephala, with over 350 species, displays polymorphism and cryptic complexes. Lacking a comprehensive DNA barcoding framework, accessible tools for species differentiation are needed for research in taxonomy, ecology, and crop management. Moreover, cuticular hydrocarbons are believed to be involved in sexual recognition mechanisms in these beetles. In the present study we examined the cuticular chemical profiles of six species from the genus Cyclocephala and two populations of Erioscelis emarginata and assessed their efficiency in population, species, and sex differentiation. Overall we identified 74 compounds in cuticular extracts of the selected taxa. Linear alkanes and unsaturated hydrocarbons were prominent, with ten compounds between them explaining 85.6% of species dissimilarity. Although the cuticular chemical profiles efficiently differentiated all investigated taxa, only C. ohausiana showed significant cuticular profile differences between sexes. Our analysis also revealed two E. emarginata clades within a larger group of ‘Cyclocephala’ species, but they were not aligned with the two studied populations. Our research underscores the significance of cuticular lipid profiles in distinguishing selected cyclocephaline beetle species and contemplates their potential impact as contact pheromones on sexual segregation and speciation.

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

Introduction

The evolutionary success of insects in terrestrial environments is indisputably related to their ability to conserve water (Garwood and Edgecombe, Reference Garwood and Edgecombe2011). One of the factors that contribute to this physiological trait is the presence of a cuticle that protects them against desiccation. The insect cuticle is a structure composed of several layers, among which the most efficient against water loss is the lipid layer associated with the epicuticle (Hadley, Reference Hadley1980). It might contain saturated or unsaturated hydrocarbons, branched or not, free fatty acids, aldehydes, alcohols, esters, ketones, glycerides, and sterols (Blomquist, Reference Blomquist, Blomquist and Bagnères2010).

Among the cuticular lipids, hydrocarbons deserve special attention because they are often present in high concentrations and play important roles in intra- and interspecific communication in insects (Lockey, Reference Lockey1991; Singer, Reference Singer1998; Howard and Blomquist, Reference Howard and Blomquist2005). Cuticular hydrocarbons (CHCs) in insects are present as a complex mixture of molecules, often characteristic of each species (Bagnères and Wicker-Thomas, Reference Bagnères, Wicker-Thomas, Blomquist and Bagnères2010). Within the same species, the CHC composition may vary between sexes (Steiger and Stökl, Reference Steiger and Stökl2014) and in relation to different life cycle stages (Lockey, Reference Lockey1991; Howard and Blomquist, Reference Howard and Blomquist2005; Thomas and Simmons, Reference Thomas and Simmons2008). Other factors such as the insects' diet (Liang and Silverman, Reference Liang and Silverman2000; Ingleby, Reference Ingleby2015), reproductive stage (Scott et al., Reference Scott, Madjid and Orians2008; Caselli et al., Reference Caselli, Favaro, Petacchi, Valicenti and Angeli2023), different populations of the same species (Hirai et al., Reference Hirai, Akino, Wakamura and Arakaki2008), and different colonies of social insects (Jutsum et al., Reference Jutsum, Saunders and Cherrett1979; Morel et al., Reference Morel, Vander Meer and Lavine1988; Dahbi et al., Reference Dahbi, Cerdá, Hefetz and Lenoir1996) as well as different castes in the same colony (Wagner et al., Reference Wagner, Brown, Broun, Cuevas, Moses, Chao and Gordon1998; Greene and Gordon, Reference Greene and Gordon2003) can alter the CHC composition both quanti- and qualitatively.

Regarding their structure, CHCs have carbon chains ranging from 11 to 43 atoms, both even and odd numbered. They are distributed into three main classes: n-alkanes, olefins, and methyl-branched alkanes. Olefins and methyl-branched alkanes usually occur as isomeric mixtures (Lockey, Reference Lockey1991; Blomquist, Reference Blomquist, Blomquist and Bagnères2010). The most common olefins in insects are alkenes, but compounds with two or, less frequently, more unsaturations may also be present. The position of the double-bonds in the carbon chain is of key relevance to their biological activities and is usually experimentally determined through derivatisation of the unsaturated compounds, followed by analysis by GC-MS (Lockey, Reference Lockey1988; Blomquist, Reference Blomquist, Blomquist and Bagnères2010).

Due to their taxon-specific character, the chemical profiles of insects' cuticles can be used to assist in species identification along with other more conventional taxonomic approaches (i.e., morphological characters and molecular biology) (Kather and Martin, Reference Kather and Martin2012). In fact, their efficiency as a chemotaxonomic tool in insect research has been demonstrated in identifying cryptic species (Soon et al., Reference Soon, Castillo-Cajas, Johansson, Paukkunen, Rosa and Ødegaard2021) and initial trends in reproductive isolation among populations (Hartke et al., Reference Hartke, Sprenger, Sahm, Winterberg, Orivel, Baur, Beuerle, Schmitt, Feldmeyer and Menzel2019).

Cyclocephaline beetles (Melolonthidae, Cyclocephalini) comprise a diverse group of essentially Neotropical Scarabaeoidea, currently encompassing ~500 spp. (Moore et al., Reference Moore, Cave and Branham2018a). Some have rhizophagous larvae, commonly referred to as white grubs, which are widely known as pests in crops, lawns, and reforestation areas (Moore et al., Reference Moore, Cave and Branham2018b). The adults of nine of the 14 currently acknowledged genera within the tribe are highly specialised pollinators and florivores that are attracted to their hosts by floral fragrances (Maia et al., Reference Maia, Dötterl, Kaiser, Silberbauer-Gottsberger, Teichert, Gibernau, do Amaral Ferraz Navarro, Schlindwein and Gottsberger2012, Reference Maia, Santos, Gonçalves, Navarro and Nuñez-Avellaneda2018; Moore et al., Reference Moore, Cave and Branham2018b). The functional details behind specific sexual recognition in these insects have only been superficially assessed (Nóbrega et al., Reference Nóbrega, Maia, Lima, Felix, Souza and Pontes2022), but it is generally agreed that close-range signals (i.e., visual, tactile, and/or chemical) might be involved.

The taxonomy of cyclocephaline beetles at the species level is primarily dependent on male genitalia characters (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018b). Therefore, it requires precise dissection, assembly, and analysis of anatomical structures, making classification challenging or even unfeasible if only females are available. Various species of the most speciose genus in the tribe, Cyclocephala (> 350 spp.), display multiple levels of polymorphism (Ratcliffe et al., Reference Ratcliffe, Cave and Cano2013, Reference Ratcliffe, Cave and Paucar-Cabrera2020), whereas others form morphologically indistinguishable complexes with cryptic species (Neita-Moreno, Reference Neita-Moreno2021). While an integrative DNA barcoding framework for the tribe Cyclocephalini has not yet been examined (Moore et al., Reference Moore, Cave and Branham2018b; Ratcliffe et al., Reference Ratcliffe, Cave and Paucar-Cabrera2020), alternative accessible tools for species differentiation could advance research not only in taxonomy but also in ecology and crop management (Lyal et al., Reference Lyal, Kirk, Smith and Smith2008; Lagomarsino and Frost, Reference Lagomarsino and Frost2020).

In the present study, we investigated the cuticular chemical profiles of six species within the genus Cyclocephala and two distinct populations of one species within the genus Erioscelis. We aimed to address the following questions: (i) Is it possible to discriminate between species based on their cuticular chemical profiles?; (ii) Are there any sex-related differences in these profiles?

Materials and methods

Investigated species and collection sites

Cyclocephala celata Dechambre, 1980: This species is found from the northeastern Atlantic Coast of Brazil across dry seasonal forests of South America to Bolivia and Paraguay (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018a). Adults are medium-sized, measuring about 15–17 mm in length. Known pollinators of Annonaceae and Araceae (Maia et al., Reference Maia, Dötterl, Kaiser, Silberbauer-Gottsberger, Teichert, Gibernau, do Amaral Ferraz Navarro, Schlindwein and Gottsberger2012; Parizotto and Grossi, Reference Parizotto and Grossi2019). Specimens used in the present study were collected in inflorescences of Philodendron acutatum Schott (Araceae) between March and June 2014 in the municipality of Igarassu, state of Pernambuco (7°49′S, 35°02′W; ca. 110 m.a.s.l.) (refer to Maia et al., Reference Maia, Schlindwein, Navarro and Gibernau2010 for details).

Cyclocephala cearae Höhne, 1923: This species is endemic to northeastern Brazil where it is found from the coastal Atlantic Forest to the Caatinga (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018a). Adults are medium-sized, measuring about 17–18 mm in length. Known pollinators of Araceae (Maia et al., Reference Maia, Gibernau, Carvalho, Gonçalves and Schlindwein2013). Specimens for the present study were collected in inflorescences of Taccarum ulei Eng. & K. Krause between March and June 2014 in the municipality of Igarassu, state of Pernambuco (7°47′S, 34°55′W; ca. 80 m.a.s.l.) (refer to Maia et al., Reference Maia, Gibernau, Carvalho, Gonçalves and Schlindwein2013 for details).

Cyclocephala paraguayensis Arrow, 1903: This species is widely distributed in South America, found north from the Colombian Orinoquia to the Chacoan Argentina and Uruguay in the south (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018a). Adults are relatively small, measuring about 11–13 mm in length. Specialised florivores associated with cacti and cultivated plants (Moore and Jameson, Reference Moore and Jameson2013). Specimens used in the present study were collected with light traps installed in a sugarcane field between March and June 2014 in the municipality of Igarassu, state of Pernambuco (7°49′S, 35°02′W; ca. 110 m.a.s.l.) (refer to Maia et al., Reference Maia, Schlindwein, Navarro and Gibernau2010 for details).

Cyclocephala distincta Burmeister, 1847: This species is widely distributed in South America, found north from Colombia and the Guianas to the southern Brazilian state of Santa Catarina (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018a). Adults are small, measuring about 9–10 mm in length. Specialised florivores associated with palms (Moore and Jameson, Reference Moore and Jameson2013; Maia et al., Reference Maia, Santos, Gonçalves, Navarro and Nuñez-Avellaneda2018). Specimens used in the present study were collected with scent-baited traps (e.g., 2-isopropyl-3-methoxypyrazine see Maia et al., Reference Maia, Santos, Gonçalves, Navarro and Nuñez-Avellaneda2018 for details) installed in a sugarcane field between December 2016 and March-April 2017 in the municipality of Igarassu, state of Pernambuco (7°49′S, 35°02′W; ca. 110 m.a.s.l.) (refer to Maia et al., Reference Maia, Schlindwein, Navarro and Gibernau2010 for details).

Cyclocephala forsteri Endrödi, 1963: This species is widely distributed in South America, found north from the Colombian Orinoquia to the southern Brazilian state of Santa Catarina (Moore et al., Reference Moore, Cave and Branham2018a). Immatures are rhizophages associated with soy crops (Santos and Ávila, Reference Santos and Ávila2007). Adults are large-sized beetles, measuring about 20–22 mm in length. Specialised florivores associated with palms (Oliveira and Ávila, Reference Oliveira and Ávila2011; Maia et al., Reference Maia, Reis, Navarro, Aristone, Colombo, Carreño‐Barrera, Núñez‐Avellaneda and Santos2020). Specimens used in the present study were collected with scent-baited traps (e.g., 4-methylanisole + 2-isopropyl-3-methoxypyrazine + 2-sec-butyl-3-methoxypyrazine) installed in a rural area ca. 30 km southeast from the municipality of Campo Grande, state of Mato Grosso do Sul (20°37′S 54°31′W; ca. 590 m.a.s.l.), between October and November 2015 (refer to Maia et al., Reference Maia, Reis, Navarro, Aristone, Colombo, Carreño‐Barrera, Núñez‐Avellaneda and Santos2020 for details).

Cyclocephala ohausiana Höhne, 1923: This species is native to the Cerrado savanna in central Brazil, as well as its transitional zone with the Atlantic Forest (Endrödi, Reference Endrödi1985; Moore et al., Reference Moore, Cave and Branham2018a). Adults are medium-sized beetles, measuring about 15–17 mm in length. Pollinators of Annonaceae (Moore and Jameson, Reference Moore and Jameson2013; Costa et al., Reference Costa, Silva, Paulino-Neto and Pereira2017). Specimens used in the present study were collected in flowers of Annona coriacea Mart. (Annonaceae) between October and November 2015 in a rural area ca. 30 km southeast from the municipality of Campo Grande, state of Mato Grosso do Sul (20°37′S 54°31′W; ca. 590 m.a.s.l.) (refer to Maia et al., Reference Maia, Reis, Navarro, Aristone, Colombo, Carreño‐Barrera, Núñez‐Avellaneda and Santos2020 for details).

Erioscelis emarginata (Mannerheim, 1829): This species is found from the coastal Atlantic Forest west to the Cerrado in Brazil, from the Chocoan Argentina to Ecuador. Adults are large-sized beetles, measuring about 21–24 mm in length. Known pollinators of Araceae (Moore and Jameson, Reference Moore and Jameson2013). Specimens used in the present study were collected in inflorescences of Philodendron bipinnatifidum Schott ex Endl. and P. mello-barretoanum R. Burle-Marx ex G.M. Barroso at two distinct locations in central Brazil. The first in the municipality of Taguatinga, Federal District, in December 2013 (15°51′S, 48°01′W; ca. 1120 m.a.s.l.). The second in the municipality of Nova Odessa, state of São Paulo, in October 2014 (22°46′S, 47°18′W; ca. 580 m.a.s.l) (refer to Barros et al., Reference Barros, Astúa, Grossi, Iannuzzi and Maia2020 for details). We considered the two collection sites as separate populations of E. emarginata, hereby referred to as ‘Taguatinga’ and ‘Nova Odessa’.

Upon collection the beetles were placed in semi-transparent plastic containers (30 × 21 × 21 cm) with perforated lids and filled with sieved and moistened pot soil. The containers were maintained at a temperature of 27 ± 2°C, relative humidity of 70 ± 5%, and a photoperiod of 14 hours of light and 10 hours of darkness for 24 to 96 hours before processing (as described below). The beetles were provided with fresh apple slices for food, which were available ad libitum.

Species identifications were conducted by Professor Paschoal Coelho Grossi, curator of the Entomological Collection at the Federal Rural University of Pernambuco (CERPE) and an expert in Dynastinae taxonomy. Voucher specimens for each species have also been deposited at CERPE.

Sampling and analysis of cuticular extracts

Female and male specimens of the seven investigated species, including two distinct populations of E. emarginata, were placed either individually or in batches of 10 (for C. distincta and C. paraguayensis) into clean 5 mL borosilicate glass vials (Sigma-Aldrich, USA). Rapid gradual freezing (−5 to −20°C; 60 min) was used to euthanise the beetles, which were then rinsed with deionised H2O to remove soil and food particles adhered to the cuticle surface. Subsequently, they were placed on clean absorbent paper to remove excess water, and dried using a stream of N 2. After drying, the specimens were put in clean borosilicate glass 5 mL vials, containing 1 ml (individual) or 2.5 ml (batch) of n-hexane (HPLC grade, bidistilled) and swirled gently for one minute. Preliminary results showed that a short-lasting extraction time minimises the interference from non-cuticular lipids, eliminating the need for a chromatographic column to purify the eluates.

The crude eluates were finally filtered using a borosilicate glass wool plug (Sigma-Aldrich, USA) packed inside a borosilicate glass Pasteur pipette into 2.0 ml (individual) or 4.0 ml (batch) chromatography vials. The extracted eluates from the batches of 10 individuals were additionally concentrated under a laminar N 2 flow to a final volume of 0.5 ml. All samples were stored under −24°C for 5 to 160 days until further processing.

The samples were analysed by gas chromatography coupled to mass spectrometry (GC-MS) using an Agilent 5975C Series GC/MSD quadrupole system (Agilent Technologies, Palo Alto, USA) equipped with an HP-5 ms non-polar column (Agilent J&W; 30 m × 0.25 mm i.d., 0.25 μm film thickness). An aliquot of 1.0 μl of each sample was injected in splitless mode. The GC oven temperature was set at 60°C for 1 min, then increased at a rate of 15°C min−1 up to 260°C, and kept for 20 min. The carrier gas (He) flow was kept constant at 1 ml min−1. MS source and quadrupole temperatures were set respectively at 230 and 150°C, and the mass spectra were recorded at 70 eV (EI mode) with a scanning speed of 0.5 scan/s from m/z 35 to 550. The compounds were identified by comparing their mass spectra and retention times to those of authentic standards available in the MassFinder 4, NIST20, Wiley Registry™ 9th Edition, and MACE_R4 (Schulz and Möllerke, Reference Schulz and Möllerke2022) reference libraries, incorporated in the software Agilent MSD Productivity ChemStation. Identification of double-bond positions in 7- and 9-alkenes was achieved through sample derivatisation (Francis and Veland, Reference Francis and Veland1987). The peak areas in the chromatograms were integrated to obtain the total ionic signal, and their values were used to determine the relative proportions of each compound. A homologous series of linear alkanes (C 9C 40) was used to determine linear retention indices (RIs) (van Den Dool and Kratz, Reference van Den Dool and Kratz1963) and provide a means for comparison with data available in the literature. Unassigned compounds corresponding to < 1% of the total individual peak area in at least one of the analysed samples were pooled.

We used the main compounds for comparative statistical analyses (see below), selected through an arbitrary threshold of ≥ 2% relative concentration (total individual peak area) in at least one of the analysed samples.

Statistical analyses

To assess differences in the cuticular lipid profiles of the seven investigated species, we first subjected the compositional chemical data (relative proportion of compounds in the samples) to a centred log ratio (clr) transformation with a 0.001 threshold to minimise misinterpretations caused by a constrained data set (as reviewed by Brückner and Heethoff, Reference Brückner and Heethoff2017). We then used the clr-transformed data to generate a two-way paired group (UPGMA) hierarchical clustering and heatmap using the Euclidean similarity index. This approach allowed us to track the influence of individual chemical compounds on the species' dendrogram.

We conducted a global permutational multivariate analyses of variance (PERMANOVA; Pseudo-F value) for the discrimination of groups/clusters recovered in the two-way UPGMA and a permutational analysis of multivariate dispersions (PERMDISP; F value) to elucidate the dispersion of the PERMANOVA.

Additionally, we ran pairwise PERMANOVA tests with the raw compositional chemical data (Bray-Curtis dissimilarity index) to assess differences between sexes (‘female’ vs ‘male’, except for C. paraguayensis), and populations (‘Taguatinga’ vs ‘Nova Odessa’, for E. emarginata only). We also conducted similarity percentages tests (SIMPER) with the raw compositional chemical data to determine the contribution of individual compounds to differences in chemical profiles among species, as well as between genera, sexes, and populations, emphasising quantitative trends. All statistical analyses were performed using PAST v.4.11 (Hammer et al., Reference Hammer, Harper and Ryan2001). Figures and graphs were edited using Adobe Illustrator 2023 (Adobe Systems Inc.).

Results

We identified 74 compounds in the solvent cuticular extracts of adult Cyclocephala spp. (n = 50 samples, six spp.) and E. emarginata (n = 51 samples, two populations). Linear alkanes (C 21 to C 34), particularly odd-chain C 21C 29, and unsaturated hydrocarbons, especially (Z)-7 and (Z)-9 odd-chain C 21C 35 alkenes, were the most well-represented cuticular lipids in all analysed samples, ranging from 94.7 to 33.2% and 66.2 to 5.1% relative composition, respectively. Fatty acyls (mostly acids and esters) and methyl-branched alkanes corresponded from null to 12.0 and 10.2%, respectively (table 1).

Table 1. Average relative amounts (%) of cuticular lipids ordered per chemical class in hexane extracts of female (♀) and male (♂) adult specimens of Cyclocephala spp. and Erioscelis emarginata (Melolonthidae. Dynastinae. Cyclocephalini).

Individuals from two populations were analysed for E. emarginata (see Materials and methods for details). Linear retention indices (RIs) were calculated based on a homologous series of linear alkanes (C9 – C40) (van Den Dool and Kratz, Reference van Den Dool and Kratz1963) and provide a means for comparison with data available in the literature. The identities of (Z)-7 and (Z)-9-alkenes were confirmed by DMDS derivatisation and comparison with RI data in mass spectral libraries (see Materials and methods for details). Compounds in bold lettering were identified in > 5% average relative concentration in at least one species and or population. The 10 compounds marked with an asterisk (*) are the main contributors to overall interspecific dissimilarity (see Results for details). Only compounds accounting for at least 1% average amount in any species are presented. Unassigned and identified compounds below this threshold were pooled as ‘Other compounds’ and their total relative percentages added. Also refer to Table Data S1 for more details.

The cuticular chemical profiles significantly differed among the seven investigated species, as evidenced by PERMANOVA (Pseudo-F = 70.04, P < 0.0001; pairwise Pseudo-F ≥ 13.83, P < 0.01) and PERMDISP (F = 67.12, P < 0.0001; pairwise F ≥ 18.31, P < 0.01). Overall, the qualitative and quantitative differences in the relative concentrations of ten compounds alone (four alkanes, six (Z)-alkenes) explained 85.6% of the dissimilarity among species.

The only species in which the cuticular chemical profiles significantly differed between sexes was C. ohausiana (Pseudo-F = 64.52, P < 0.0001), with an overall average dissimilarity of 65.2% that was mostly explained by differential occurrence and relative proportions of C 21 and C 23 (Z)-alkenes and linear alkanes, as well as a heneicosadiene of unknown structure (RI 2072) (refer to table 1 for details).

In the UPGMA dendrogram and heatmap, we can visually observe a distinct separation of all examined taxa into discrete clades (fig. 1). Notably, we identified two sister clades of E. emarginata within a larger group that encompasses all Cyclocephala species. It is worth highlighting that these two E. emarginata clades did not correspond to the ‘Nova Odessa’ and ‘Taguatinga’ populations we investigated, as the largest clade included samples from both populations (fig. 1). Nevertheless, a pairwise PERMANOVA test provided statistical support for the differentiation between these two populations (Pseudo-F = 61.14, P < 0.0001).

Figure 1. Paired group (UPGMA) two-way dendrogram and heat map of the cuticular chemical profiles of Cyclocephala spp. and Erioscelis emarginata (Melolonthidae, Dynastinae, Cyclocephalini) using centred log ratio (clr)-transformed compositional chemical data (relative proportion of compounds in the samples). Each column correspond to one sample (see Materials and methods for details) and each row to a cuticular lipid identified by GC-MS analysis. Arrows mark the rows of the compounds that contributed most to clade formation in a similarity percentages test (SIMPER) with the raw compositional chemical data. Only compounds accounting for at least 2% average amount in any species (35 in total) were used for the analysis (see Materials and methods for details).

Discussion

The cuticular lipid profiles of the seven Cyclocephalini species investigated in our study exhibited high relative concentrations of odd, very long-chain (>C 20; VLC) n-alkanes and (Z)-alkenes. These compounds are widely found in the epicuticles of various insect groups, including Scarabaeoid beetles (Blomquist, Reference Blomquist, Blomquist and Bagnères2010). Interestingly, the identities and relative proportions of these compounds were highly effective in explaining the well-supported species groupings observed in our study. In fact, a mere ten compounds (out of 77 identified in total) accounted for over 85% of the dissimilarity among species.

In a chemotaxonomic analysis of Mediterranean earth-boring dung beetles (Geotrupidae), Niogret et al. (Reference Niogret, Felix, Nicot and Lumaret2019) identified the presence of n-alkanes and (Z)-alkenes in the cuticular lipid profiles of all 12 species studied. The relative concentrations of these compounds varied, ranging from 4.8 to 17.3% for n-alkanes and 0.9 to 14.0% for (Z)-alkenes. Similar findings were reported by Fletcher et al. (Reference Fletcher, Allsopp, McGrath, Chow, Gallagher, Hull, Cribb, Moore and Kitching2008) in a study involving six Australian species of Scarabaeidae, where all species except one exhibited the presence of n-alkanes or (Z)-alkenes in their cuticular profiles. However, unlike our study, both investigations found that methyl-branched alkanes were also significantly abundant, accounting for anywhere between 12 and 83% of the relative concentration of cuticular lipids.

Although VLC-alkanes are commonly found in the epicuticles of insects (Blomquist, Reference Blomquist, Blomquist and Bagnères2010) and have been identified as pheromonal components in various taxa (El-Sayed, Reference El-Sayed2023), their precise role in chemical communication among beetles remains poorly understood (Howard and Blomquist, Reference Howard and Blomquist2005). It is widely recognised that the molecular discriminative features of VLC-alkanes are relatively limited, being primarily based on carbon-chain length (van Zweden and d'Ettorre, Reference van Zweden, d'Ettorre, Blomquist and Bagnères2010). The variation in VLC-alkane proportions observed across different insect species, populations, sexes, and castes, nonetheless, provides support for their influence on behavioural modulation (van Zweden and d'Ettorre, Reference van Zweden, d'Ettorre, Blomquist and Bagnères2010).

On the other hand, (Z)-alkenes and methyl-branched alkanes possess greater potential as informative semiochemicals based on their molecular structure. This is attributed to factors such as the position of the methyl group or double-bond, and stereoisomerism (van Zweden and d'Ettorre, Reference van Zweden, d'Ettorre, Blomquist and Bagnères2010). In the case of beetles, (Z)-7 and (Z)-9-alkenes with odd-chain lengths ranging from C 23 to C 29 have been found to elicit contact-based sexually-oriented behaviour in various species of Cerambycidae (as reviewed by Ginzel, Reference Ginzel, Blomquist and Bagnères2010). Therefore, it is plausible that the presence of these compounds in the cuticular lipid profiles of Scarabaeiodea species could serve similar functions. The same can be said for methyl-branched alkanes, which can act as highly specific constituents of sex or aggregation pheromones due to their variability and chiral nature (van Zweden and d'Ettorre, Reference van Zweden, d'Ettorre, Blomquist and Bagnères2010). While our current findings are derived from a limited sampling effort, we propose further exploration of the potential involvement of unsaturated and methyl-branched alkanes in contact-based chemical communication among cyclocephaline beetles. In this context, it is also worth highlighting the alkadienes present in significant relative proportions in the cuticular lipid profiles of two of the studied species, namely C. ohausiana and C. paraguayensis.

We were surprised to find that sex-related differences were only evident in one of the taxa investigated in our study. This finding is intriguing considering the highly aggregative behaviour observed in flower-loving species of cyclocephaline beetles, often comprised by hundreds (Gottsberger and Silberbauer-Gottsberger, Reference Gottsberger and Silberbauer-Gottsberger1991; Scariot et al., Reference Scariot, Lleras and Hay1991), even thousands (Henderson, Reference Henderson1986; Núñez, Reference Núñez Avellaneda2014), of individuals. It is also worth noting that these aggregations regularly consist of multiple species coexisting (Beach, Reference Beach1982; Young, Reference Young1986; Maia et al., Reference Maia, Gibernau, Carvalho, Gonçalves and Schlindwein2013; Costa et al., Reference Costa, Silva, Paulino-Neto and Pereira2017), a context that has led to speculation about the potential role of contact or short-range chemical communication in sex recognition among these beetles (Nóbrega et al., Reference Nóbrega, Maia, Lima, Felix, Souza and Pontes2022). Such communication mechanisms could serve to prevent both same-sex pairing and interspecific copulation.

Indirect evidence of intraspecific contact chemical communication in cyclocephaline beetles has been obtained through controlled rearing experiments involving various species of Cyclocephala (Rodrigues et al., Reference Rodrigues, Nogueira, Echeverria and Oliveira2010; Nogueira et al., Reference Nogueira, Rodrigues and Tiago2013; Souza et al., Reference Souza, Maia, Schlindwein, Albuquerque and Iannuzzi2014). These experiments have demonstrated successful copulation and egg fertilisation occurring in small aggregations or even in one-on-one pairings, indicating at least some level of sex differentiation. Notably, Nóbrega et al. (Reference Nóbrega, Maia, Lima, Felix, Souza and Pontes2022) propose that male C. distincta are capable of distinguishing conspecific females upon contact, and that specific innate female traits trigger male sexual behaviour. This suggests that contact-based chemical cues play a crucial role in facilitating reproductive interactions within the species.

It is important to note that when examining trap collections and directly assessing insects within flowers, a consistent observation is that the female-to-male sex ratios of cyclocephaline beetles typically range from 1:1 to 2:1 (Beach, Reference Beach1982; Albuquerque et al., Reference Albuquerque, Grossi and Iannuzzi2016; Maia et al., Reference Maia, Reis, Navarro, Aristone, Colombo, Carreño‐Barrera, Núñez‐Avellaneda and Santos2020). This finding indicates that, on average, males within species-specific aggregations achieve a copulation success rate of approximately 50 to 75% from their random mating attempts.

It is likely that within the range of interactions between cyclocephaline beetles and their host plants, spanning from highly specialised (monophily) to more generalised (polyphily), species with a narrower preference (oligophilous) are increasingly dependent on floral scents to ensure their reproductive success. This scenario seems to be evident in diverse coastal forest ecosystems of French Guiana, where several co-flowering species of Araceae (such as Philodendron, Dieffenbachia, and Montrichardia) are each exclusively visited by a unique species or subset of species (Gibernau et al., Reference Gibernau, Barabé, Cerdan and Dejean1999, Reference Gibernau, Barabé, Labat, Cerdan and Dejean2003; Gibernau and Barabé, Reference Gibernau and Barabé2002; Gibernau, Reference Gibernau2015). This intricate interplay between specific floral hosts and distinct beetle species underscores the importance of chemical signals in facilitating successful reproductive interactions.

A contrasting scenario unfolds in the interactions involving large-flowered Annona spp., specifically A. coriacea, in the Cerrado savanna ecosystems of central Brazil. These nocturnally blooming flowers attract at least seven potentially syntopic species of Cyclocephala, including C. ohausiana (Costa et al., Reference Costa, Silva, Paulino-Neto and Pereira2017). Within the floral chambers of Annona spp., multiple congeneric species often aggregate together, creating a complex ecological milieu. This coexistence of closely related species may impose selective pressures that drive the development of more efficient mechanisms for contact-based sex discrimination. It is conceivable that these selective pressures contribute to the observed significant sex differences in the cuticular lipid profiles of C. ohausiana.

Our research findings underscore the significance of cuticular lipid profiles as robust tools for distinguishing among specific flower-loving cyclocephaline beetle species. These findings hold particular relevance in the identification of cryptic species groups, notably within the Cyclocephala genus, such as the black species documented by Neita-Moreno (Reference Neita-Moreno2021), as well as the ‘sexpunctata’ and ‘latericia’ species complexes (Moore, Reference Moore2011; Santos, Reference Santos2014), among others. Moreover, our study emphasises the imperative need for further research to establish appropriate comparative methodologies, enabling the investigation of variations in contact communication among cyclocephaline beetle species in diverse ecological conditions. Such research is pivotal in comprehending the spectrum of interactions involving cyclocephaline beetles and their floral hosts, ranging from monophily to polyphily. The chemotaxonomic characteristics of lipid profiles in cyclocephaline beetles, coupled with the potential involvement of CHCs in intraspecific chemical communication, highlight prospective applications in the realms of rapid taxonomic assignment and the targeted management of pest species. As previously illustrated by Potter and Haynes (Reference Potter and Haynes1993), non-polar solvent extracts derived from female southern masked chafers (Cyclocephala borealis Arrow, 1911) trigger sex-specific male behaviour. This intriguing phenomenon can be leveraged in strategies encompassing selective baiting, mass captures, or sexual disruption techniques.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0007485323000664

Acknowledgements

The authors express their gratitude to Paschoal Coelho Grossi for identifying the beetles. Additionally, we extend our thanks to Eduardo Gomes Gonçalves and Rafaella de Lucena Nóbrega for their assistance in collecting E. emarginata specimens in Taguatinga and C. distincta specimens in Igarassu, respectively. We would also like to acknowledge the invaluable support of Sílvio Columbelli and Wesley Nantes during fieldwork in Mato Grosso do Sul. ACDM is sincerely grateful for the hospitality extended by Harri Lorenzi, founder of the Plantarum Institute in Nova Odessa. ACDM and GKNS were partially supported by scholarships from the Coordenação de Aperfeiçoamento de Nível Superior (CAPES). DMAF acknowledges the financial support provided by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, 306351/2022-6) and FACEPE (APQ-0443-1.06/15). The author(s) received no direct funding to support the research, authorship, and/or publication of this article.

Competing interests

None.

References

Albuquerque, LSCD, Grossi, PC and Iannuzzi, L (2016) Flight patterns and sex ratio of beetles of the subfamily Dynastinae (Coleoptera, Melolonthidae). Revista Brasileira de Entomologia 60, 248254.CrossRefGoogle Scholar
Bagnères, A-G and Wicker-Thomas, C (2010) Introduction: history and overview of insect hydrocarbons. In Blomquist, GJ and Bagnères, A-G (eds), Insect Hydrocarbons: Biology, Biochemistry, and Chemical Ecology. New York, USA: Cambridge University Press, pp. 318.Google Scholar
Barros, RP, Astúa, D, Grossi, PC, Iannuzzi, L and Maia, ACD (2020) Landmark-based geometric morphometrics as a tool for the characterization of biogeographically isolated populations of the pollinator scarab beetle Erioscelis emarginata (Coleoptera: Melolonthidae). Zoologischer Anzeiger 288, 97102.CrossRefGoogle Scholar
Beach, JH (1982) Beetle pollination of Cyclanthus bipartitus (Cyclanthaceae). American Journal of Botany 69, 10741081.CrossRefGoogle Scholar
Blomquist, GJ (2010) Structure and analysis of insect hydrocarbons. In Blomquist, GJ and Bagnères, A-G (eds), Insect Hydrocarbons: Biology, Biochemistry, and Chemical Ecology. New York, USA: Cambridge University Press, pp. 1934.CrossRefGoogle Scholar
Brückner, A and Heethoff, M (2017) A chemo-ecologists’ practical guide to compositional data analysis. Chemoecology 27, 3346.CrossRefGoogle Scholar
Caselli, A, Favaro, R, Petacchi, R, Valicenti, M and Angeli, S (2023) The cuticular hydrocarbons of Dasineura oleae show differences between sex, adult age and mating status. Journal of Chemical Ecology 49, 369383.CrossRefGoogle ScholarPubMed
Costa, MS, Silva, RJ, Paulino-Neto, HF and Pereira, MJB (2017) Beetle pollination and flowering rhythm of Annona coriacea Mart.(Annonaceae) in Brazilian cerrado: behavioral features of its principal pollinators. PLoS One 12, e0171092.CrossRefGoogle ScholarPubMed
Dahbi, A, Cerdá, X, Hefetz, A and Lenoir, A (1996) Social closure, aggressive behavior, and cuticular hydrocarbon profiles in the polydomous ant Cataglyphis iberica (Hymenoptera, Formicidae). Journal of Chemical Ecology 22, 21732186.CrossRefGoogle Scholar
El-Sayed, AM (2023) The Pherobase: Database of Pheromones and Semiochemicals. Available at https://www.pherobase.comGoogle Scholar
Endrödi, S (1985) The Dynastinae of the World (Series Entomologica V. 28). Hungary: Budapest: Dr W. Junk Publishers.Google Scholar
Fletcher, MT, Allsopp, PG, McGrath, MJ, Chow, S, Gallagher, OP, Hull, C, Cribb, BW, Moore, CJ and Kitching, W (2008) Diverse cuticular hydrocarbons from Australian canebeetles (Coleoptera: Scarabaeidae). Australian Journal of Entomology 47, 153159.CrossRefGoogle Scholar
Francis, GW and Veland, K (1987) Alkylthiolation for the determination of double-bond positions in linear alkenes. Journal of Chromatography A 219, 379384.CrossRefGoogle Scholar
Garwood, RJ and Edgecombe, GD (2011) Early terrestrial animals, evolution, and uncertainty. Evolution: Education and Outreach 4, 489501.Google Scholar
Gibernau, M (2015) Pollination ecology of two Dieffenbachia in French Guiana. Aroideana 38E, 3866.Google Scholar
Gibernau, M and Barabé, D (2002) Pollination ecology of Philodendron squamiferum (Araceae). Canadian Journal of Botany 80, 316320.CrossRefGoogle Scholar
Gibernau, M, Barabé, D, Cerdan, P and Dejean, A (1999) Beetle pollination of Philodendron solimoesense (Araceae) in French Guiana. International Journal of Plant Sciences 160, 11351143.CrossRefGoogle ScholarPubMed
Gibernau, M, Barabé, D, Labat, D, Cerdan, P and Dejean, A (2003) Reproductive biology of Montrichardia arborescens (Araceae) in French Guiana. Journal of Tropical Ecology 19, 103107.CrossRefGoogle Scholar
Ginzel, MD (2010) Hydrocarbons as contact pheromones of longhorned beetles (Coleoptera: cerambycidae). In Blomquist, GJ and Bagnères, A-G (eds), Insect Hydrocarbons: Biology, Biochemistry, and Chemical Ecology. New York, USA: Cambridge University Press, pp. 375389.CrossRefGoogle Scholar
Gottsberger, G and Silberbauer-Gottsberger, I (1991) Olfactory and visual attraction of Erioscelis emarginata (Cyclocephalini, Dynastinae) to the inflorescences of Philodendron selloum (Araceae). Biotropica 23, 2328.CrossRefGoogle Scholar
Greene, MJ and Gordon, DM (2003) Cuticular hydrocarbons inform task decisions. Nature 423, 3232.CrossRefGoogle ScholarPubMed
Hadley, NF (1980) Surface waxes and integumentary permeability: lipids deposited on or associated with the surface of terrestrial plants and animals help protect them from a lethal rate of desiccation. American Scientist 68, 546553.Google Scholar
Hammer, Ø, Harper, DA and Ryan, PD (2001) PAST: Paleontological statistics software package for education and data analysis. Palaeontologia Electronica 4, 9.Google Scholar
Hartke, J, Sprenger, PP, Sahm, J, Winterberg, H, Orivel, J, Baur, H, Beuerle, T, Schmitt, T, Feldmeyer, B and Menzel, F (2019) Cuticular hydrocarbons as potential mediators of cryptic species divergence in a mutualistic ant association. Ecology and Evolution 9, 91609176.CrossRefGoogle Scholar
Henderson, A (1986) A review of pollination studies in the Palmae. The Botanical Review 52, 221259.CrossRefGoogle Scholar
Hirai, Y, Akino, T, Wakamura, S and Arakaki, N (2008) Morphological and chemical comparison of males of the white grub beetle Dasylepida ishigakiensis (Coleoptera: Scarabaeidae) among four island populations in the Sakishima Islands of Okinawa. Applied Entomology and Zoology 43, 6572.CrossRefGoogle Scholar
Howard, RW and Blomquist, GJ (2005) Ecological, behavioral, and biochemical aspects of insect hydrocarbons. Annual Review of Entomology 50, 371393.CrossRefGoogle ScholarPubMed
Ingleby, FC (2015) Insect cuticular hydrocarbons as dynamic traits in sexual communication. Insects 6, 732742.CrossRefGoogle ScholarPubMed
Jutsum, AR, Saunders, TS and Cherrett, JM (1979) Intraspecific aggression is the leaf-cutting ant Acromyrmex octospinosus. Animal Behavior 27, 839844.CrossRefGoogle Scholar
Kather, R and Martin, SJ (2012) Cuticular hydrocarbon profiles as a taxonomic tool: advantages, limitations and technical aspects. Physiological Entomology 37, 2532.CrossRefGoogle Scholar
Lagomarsino, LP and Frost, LA (2020) The central role of taxonomy in the study of neotropical biodiversity. Annals of the Missouri Botanical Garden 105, 405421.CrossRefGoogle Scholar
Liang, D and Silverman, J (2000) “You are what you eat”: diet modifies cuticular hydrocarbons and nestmate recognition in the Argentine ant, Linepithema humile. Naturwissenschaften 87, 412416.CrossRefGoogle Scholar
Lockey, KH (1988) Lipids of the insect cuticle: origin, composition and function. Comparative Biochemistry and Physiology Part B: Comparative Biochemistry 89, 595645.CrossRefGoogle Scholar
Lockey, KH (1991) Insect hydrocarbon classes: implications for chemotaxonomy. Insect Biochemistry 21, 9197.CrossRefGoogle Scholar
Lyal, C, Kirk, P, Smith, D and Smith, R (2008) The value of taxonomy to biodiversity and agriculture. Biodiversity 9, 813.CrossRefGoogle Scholar
Maia, ACD, Schlindwein, C, Navarro, DMAF and Gibernau, M (2010) Pollination of Philodendron acutatum (Araceae) in the Atlantic forest of northeastern Brazil: a single scarab beetle species guarantees high fruit set. International Journal of Plant Sciences 171, 740748.CrossRefGoogle Scholar
Maia, AC, Dötterl, S, Kaiser, R, Silberbauer-Gottsberger, I, Teichert, H, Gibernau, M, do Amaral Ferraz Navarro, DM, Schlindwein, C and Gottsberger, G (2012) The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal of Chemical Ecology 38, 10721080.Google ScholarPubMed
Maia, ACD, Gibernau, M, Carvalho, AT, Gonçalves, EG and Schlindwein, C (2013) The cowl does not make the monk: scarab beetle pollination of the Neotropical aroid Taccarum ulei (Araceae: Spathicarpeae). Biological Journal of the Linnean Society 108, 2234.CrossRefGoogle Scholar
Maia, ACD, Santos, GKN, Gonçalves, EG, Navarro, DMDAF and Nuñez-Avellaneda, LA (2018) 2-Alkyl-3-methoxypyrazines are potent attractants of florivorous scarabs (Melolonthidae, Cyclocephalini) associated with economically exploitable Neotropical palms (Arecaceae). Pest Management Science 74, 20532058.CrossRefGoogle Scholar
Maia, ACD, Reis, LK, Navarro, DM, Aristone, F, Colombo, CA, Carreño‐Barrera, J, Núñez‐Avellaneda, LA and Santos, GK (2020) Chemical ecology of Cyclocephala forsteri (Melolonthidae), a threat to macauba oil palm cultivars (Acrocomia aculeata, Arecaceae). Journal of Applied Entomology 144, 3340.CrossRefGoogle Scholar
Moore, MR (2011) Disentangling the phenotypic variation and pollination biology of the Cyclocephala sexpunctata species complex (Coleoptera: Scarabaeidae: Dynastinae) (Unpublished MSc thesis). Wichita State University.Google Scholar
Moore, MR and Jameson, ML (2013) Floral associations of cyclocephaline scarab beetles. Journal of Insect Science 13, 100.CrossRefGoogle ScholarPubMed
Moore, MR, Cave, RD and Branham, MA (2018a) Annotated catalog and bibliography of the cyclocephaline scarab beetles (Coleoptera, Scarabaeidae, Dynastinae, Cyclocephalini). ZooKeys 745, 101378.CrossRefGoogle Scholar
Moore, MR, Cave, RD and Branham, MA (2018b) Synopsis of the cyclocephaline scarab beetles (Coleoptera, Scarabaeidae, Dynastinae). ZooKeys 745, 199.CrossRefGoogle Scholar
Morel, L, Vander Meer, RK and Lavine, BK (1988) Ontogeny of nestmate recognition cues in the red carpenter ant (Camponotus floridanus). Behavioral Ecology and Sociobiology 22, 175183.CrossRefGoogle Scholar
Neita-Moreno, JC (2021) A review of the black species of Cyclocephala Dejean (Coleoptera: Scarabaeidae: Dynastinae) from Colombia. Zootaxa 5026, 158.CrossRefGoogle ScholarPubMed
Niogret, J, Felix, AE, Nicot, A and Lumaret, JP (2019) Chemosystematics using cuticular compounds: a powerful tool to separate species in Mediterranean dung beetles (Coleoptera: Geotrupidae). Journal of Insect Science 19, 18.CrossRefGoogle ScholarPubMed
Nóbrega, RL, Maia, ACD, Lima, CHM, Felix, KES, Souza, TB and Pontes, WJT (2022) Behavioral traits and sexual recognition: multiple signaling in the reproductive behavior of Cyclocephala distincta (Melolonthidae, Cyclocephalini). Anais da Academia Brasileira de Ciências 94, e20200694.CrossRefGoogle ScholarPubMed
Nogueira, GAL, Rodrigues, SR and Tiago, EF (2013) Biological aspects of Cyclocephala tucumana Brethes, 1904 and Cyclocephala melanocephala (Fabricius, 1775) (Coleoptera: Scarabaeidae). Biota Neotropica 13, 8690.CrossRefGoogle Scholar
Núñez Avellaneda, LA (2014) Patrones de asociación entre insectos polinizadores y palmas silvestres en Colombia con énfasis en palmas de importancia económica (Unpublished PhD thesis). Universidad Nacional de Colombia.Google Scholar
Oliveira, HN and Ávila, CJ (2011) Ocorrência de Cyclocephala forsteri em Acronomia aculeata. Pesquisa Agropecuária Tropical 41, 293295.CrossRefGoogle Scholar
Parizotto, DR and Grossi, PC (2019) Revisiting pollinating Cyclocephala scarab beetles (Coleoptera: Melolonthidae: Dynastinae) associated with the soursop (Annona muricata, Annonaceae). Neotropical Entomology 48, 415421.CrossRefGoogle ScholarPubMed
Potter, DA and Haynes, KF (1993) Field-testing pheromone traps for predicting masked chafer (Coleoptera: Scarabaeidae) grub density in golf course turf and home lawns. Journal of Entomological Science 28, 205212.CrossRefGoogle Scholar
Ratcliffe, BC, Cave, RD and Cano, E (2013) The dynastine scarab beetles of Mexico, Guatemala, and Belize (Coleoptera: Scarabaeidae). Bulletin of the University of Nebraska State Museum 27, 1666.Google Scholar
Ratcliffe, BC, Cave, RD and Paucar-Cabrera, A (2020) The dynastine scarab beetles of Ecuador (Coleoptera: Scarabaeidae: Dynastinae). Bulletin of the University of Nebraska State Museum 32, 1586.Google Scholar
Rodrigues, SR, Nogueira, GA, Echeverria, RR and Oliveira, VS (2010) Aspectos biológicos de Cyclocephala verticalis Burmeister (Coleoptera: Scarabaeidae). Neotropical Entomology 39, 1518.CrossRefGoogle Scholar
Santos, MD (2014) Revisão do grupo “latericia” do gênero Cyclocephala Dejean, 1821 (Melolonthidae, Dynastinae, Cyclocephalini) (Unpublished BSc dissertation). Universidade Federal do Paraná.Google Scholar
Santos, V and Ávila, CJ (2007) Aspectos bioecológicos de Cyclocephala forsteri Endrodi, 1963 (Coleoptera: Melolonthidae) no estado do Mato Grosso do Sul. Brazilian Journal of Agriculture 82, 298303.Google Scholar
Scariot, AO, Lleras, E and Hay, JD (1991) Reproductive biology of the palm Acrocomia aculeata in Central Brazil. Biotropica 23, 1222.CrossRefGoogle Scholar
Schulz, S and Möllerke, A (2022) MACE – an open access data repository of mass spectra for chemical ecology. Journal of Chemical Ecology 48, 589597.CrossRefGoogle ScholarPubMed
Scott, MP, Madjid, K and Orians, CM (2008) Breeding alters cuticular hydrocarbons and mediates partner recognition by burying beetles. Animal Behaviour 76, 507513.CrossRefGoogle Scholar
Singer, TL (1998) Roles of hydrocarbons in the recognition systems of insects. American Zoologist 38, 394405.CrossRefGoogle Scholar
Soon, V, Castillo-Cajas, RF, Johansson, N, Paukkunen, J, Rosa, P, Ødegaard, F, et al. (2021) Cuticular hydrocarbon profile analyses help clarify the species identity of dry-mounted cuckoo wasps (Hymenoptera: Chrysididae), including type material, and reveal evidence for a cryptic species. Insect Systematics and Diversity 5, 3.CrossRefGoogle Scholar
Souza, TB, Maia, ACD, Schlindwein, C, Albuquerque, LSC and Iannuzzi, L (2014) The life of Cyclocephala celata Dechambre, 1980 (Coleoptera: Scarabaeidae: Dynastinae) in captivity with descriptions of the immature stages. Journal of Natural History 48, 275283.CrossRefGoogle Scholar
Steiger, S and Stökl, J (2014) The role of sexual selection in the evolution of chemical signals in insects. Insects 5, 423438.CrossRefGoogle ScholarPubMed
Thomas, ML and Simmons, LW (2008) Sexual dimorphism in cuticular hydrocarbons of the Australian field cricket Teleogryllus oceanicus (Orthoptera: Gryllidae). Journal of Insect Physiology 54, 10811089.CrossRefGoogle ScholarPubMed
van Den Dool, H and Kratz, PD (1963) A generalization of the retention index system including linear temperature programmed gas-liquid partition chromatography. Journal of Chromatography 11, 463471.CrossRefGoogle Scholar
van Zweden, JS and d'Ettorre, P (2010) The role of hydrocarbons in nestmate recognition. In Blomquist, GJ and Bagnères, A-G (eds), Insect Hydrocarbons: Biology, Biochemistry, and Chemical Ecology. New York, USA: Cambridge University Press, pp. 222243.CrossRefGoogle Scholar
Wagner, D, Brown, MJ, Broun, P, Cuevas, W, Moses, LE, Chao, DL and Gordon, DM (1998) Task-related differences in the cuticular hydrocarbon composition of harvester ants, Pogonomyrmex barbatus. Journal of Chemical Ecology 24, 20212037.CrossRefGoogle Scholar
Young, HJ (1986) Beetle pollination of Dieffenbachia longispatha (Araceae). American Journal of Botany 73, 931944.CrossRefGoogle Scholar
Figure 0

Table 1. Average relative amounts (%) of cuticular lipids ordered per chemical class in hexane extracts of female (♀) and male (♂) adult specimens of Cyclocephala spp. and Erioscelis emarginata (Melolonthidae. Dynastinae. Cyclocephalini).

Figure 1

Figure 1. Paired group (UPGMA) two-way dendrogram and heat map of the cuticular chemical profiles of Cyclocephala spp. and Erioscelis emarginata (Melolonthidae, Dynastinae, Cyclocephalini) using centred log ratio (clr)-transformed compositional chemical data (relative proportion of compounds in the samples). Each column correspond to one sample (see Materials and methods for details) and each row to a cuticular lipid identified by GC-MS analysis. Arrows mark the rows of the compounds that contributed most to clade formation in a similarity percentages test (SIMPER) with the raw compositional chemical data. Only compounds accounting for at least 2% average amount in any species (35 in total) were used for the analysis (see Materials and methods for details).

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