Qualitative and quantitative differences in cuticular hydrocarbons between laboratory and field colonies of Pogonomyrmex barbatus

Ants held in the laboratory and field ants of the species Pogonomyrmex barbatus have quantitative differences in their cuticular hydrocarbons and a qualitative difference in their methyl-branched hydrocarbons. Laboratory-held workers showed twice the hydrocarbon content as field ants. This difference was mainly due to higher amounts of straight-chain alkanes and methyl-branched alkanes in laboratory ants, whereas the proportion of the alkenes remained the same for both groups. In addition to the absence of some hydrocarbons in the field colonies, one of the methyl-branched hydrocarbons differed in amount and branching pattern between the two groups of ants. Whereas, notable peaks of 2-methylalkanes were identified in ants kept in the laboratory, these compounds could not be identified in ants living in their natural habitat. However, a trace amount of 4-methyltriacontane was found in lieu of the 2-methyltriacontane counterpart in field ants. Possible explanations for both qualitative and quantitative differences are discussed.     

The subepithelial gland in ants: a novel exocrine gland closely associated with the cuticle surface

Two glandular systems were discovered that secrete their products onto the cuticular surface in ants. The first, the subepithelial gland, was previously undescribed in ants, and is found throughout the body just beneath the epithelium. This gland consists of independent secretory units, each made up of a single gland cell and an associated duct cell that penetrates the cuticle. Its ultrastructural appearance is consistent with possible hydrocarbon production. Examining 84 ant species, the subepithelial gland was found in eight subfamilies (out of 13), although not necessarily in all species. In a single ant species, Harpegnathos saltator, it was the epithelium itself that was enlarged and functioned as a gland. The enlarged epithelial cells secrete their products directly onto the cuticle through distinct cuticular crevasses.     

Dynamics of aggregation in <Emphasis Type="Italic">Lasius niger</Emphasis> (Formicidae): influence of polyethism

Summary Polyethism is a well-known phenomenon in social insects. How this phenomenon influences interactions among individuals, the spatial distribution in the nest is, on the other hand, very rarely documented. Therefore, we conducted experiments on the ant Lasius niger to observe the influence of polyethism on aggregation, by distinguishing two groups of ants: the brood-tenders and the foragers. We show a great difference in their self aggregation level. Brood-tenders are characterized by a rapid and dense gathering in one main stable cluster while foragers gather in several small unstable clusters. We show experimentally and verify with a model that this difference in behaviour is based on a smaller probability of leaving a cluster for the brood-tenders. Aggregation in the mixed case (groups composed of brood-tenders and foragers) is very close to that of the pure forager case, showing a decrease in the level of aggregation of the brood-tenders respecting to the pure group of brood-tenders. Nevertheless, experimental results supported by the results of the model, show that ants do not change their own behaviour when the two groups are together. Therefore, the decrease of the aggregation of brood-tenders in the mixed case can be explained by a difference in the dynamics between brood-tenders and foragers.Received 9 May 2003; revised 26 August 2003; accepted 1 September 2003.     

Cuticular hydrocarbons of the flea beetles,Aphthona lacertosa and Aphthona nigriscutis,biocontrol agents for leafy spurge (Euphorbia esula)

The adult beetles Aphthona lacertosa and Aphthona nigriscutis, used as biocontrol agents for leafy spurge, had a complex mixture of hydrocarbons on their cuticular surface consisting of alkanes, methylalkanes, alkenes and alkadienes as determined by gas chromatography-mass spectrometry. A trace amount of wax esters were present. In both species, the hydrocarbons were the major cuticular lipid class and the gas chromatographic profiles of the total hydrocarbons were similar. However, the profiles for the saturated hydrocarbon fraction were distinct for each species. Alkanes (n-alkanes and methyl-branched alkanes), alkenes and alkadienes comprised 26, 44 and 30%, respectively, for A. lacertosa, and 48, 26 and 26%, respectively, for A. nigriscutis, of the total hydrocarbons. The major methyl-branched hydrocarbons were 2-methylalkanes: 2-methyloctacosane and 2-methyltriacontane. The major monoene was hentriacontene and the major diene was tritriacontadiene. The species were unique in that a number of di- and trimethyl-branched alkanes were present in minor quantities in which the first methyl branch was on carbon 2 or 3. Examples of structures were 2,10-, 2,12-, 2,6-, 2,4- and 3,7-dimethylalkanes. 2,10,12-Trimethylalkanes and a 2,10,12,24-tetramethylalkane with one methylene between adjacent methyl branch points also were identified. The adjacent methyl branch points of the 2,4- and 2,10,12- and 2,10,12,24-methyl-branched alkanes appeared to cause additional fragmentations in the mass spectra. Dimethylalkanes with an odd number of carbons in the backbone of the molecule were identified as 2,23-dimethylnonacosane and 2,25-dimethylhentriacontane; their mass spectra also corresponded to mass spectra expected for a 2,6 branching sequence. However, a 2,6 branching sequence is not biosynthetically feasible because such a structure has a straight-chain tail with an odd number of carbon atoms beyond the last methyl branch point. The 2,23 and 2,25 branching sequences could be synthesized starting with a primer derived from the amino acid leucine which would account for both the even number of carbons between the branch points and an even number of carbons beyond the last methyl branch point.     

Correlation between mandibular gland secretion and cuticular hydrocarbons in the stingless bee Melipona quadrifasciata

We investigated whether Melipona quadrifasciata worker mandibular gland secretions contribute directly to their cuticular hydrocarbon profile. The mandibular gland secretion composition and cuticular surface compounds of newly emerged worker bees, nurse bees, and foragers were determined by gas chromatography and mass spectrometry and compared. Both the mandibular gland secretions and the cuticular surface compounds of all worker stages were found to be composed almost exclusively of hydrocarbons. Although the relative proportion of hydrocarbons from the cuticular surface and gland secretion was statistically different, there was a high similarity in the qualitative composition between these structures in all groups of bees.     

Sex, age and ovarian activity affect cuticular hydrocarbons in Diacamma ceylonense, a queenless ant

In the queenless ant, Diacamma ceylonense, the cuticular hydrocarbons (C25-C35) of nestmate workers vary in their proportions according to age and fertility. Newly eclosed adults ('callows') initially have the same cuticular profile, but with time this changes to that typical of foragers. In contrast, workers that begin to produce eggs develop a different cuticular profile. Several substances (n-C29 and some methyl C25 and C27) discriminate these different social categories (callows, foragers and egg-layers). In Diacamma ceylonense, inter-colony variation of the cuticular hydrocarbons was much lower than intra-colony variation. We also found qualitative differences between the sexes, with males having a clearly different profile with much more alkanes. We discuss these results in the context of physiological models of the relation between ovarian activity and the synthesis of cuticular hydrocarbons. Variations in cuticular profile are a reliable reflection of ovarian activity, and could be used by ants as a fertility signal.     

Task-Related Variation of Cuticular Hydrocarbon Profiles Affect Nestmate Recognition in the Giant ant Dinoponera quadriceps

Recognition seems to be one of the more remarkable characteristics of social groups. In social insects, cuticular hydrocarbons are important for colonial recognition by providing a chemical signature for colony members. The acceptance threshold model predicts that colony members will accept conspecifics when the levels of nest mate cues dissimilarities are below the acceptance threshold. We tested the hypothesis that the encounter of a guard ant worker with a nurse may cause a delay in the process of recognition, because nurses from distinct colonies may share greater amount of chemical compounds. Dinoponera quadriceps guard workers decreased their effectiveness to recognize nurses rather than did to foragers. Alien foragers received significantly more bites and other stronger acts than non-nestmate nurses when they were experimentally introduced. In addition, guards took significantly more time to react against non-nestmate nurses than against alien foragers. Analysis of the cuticular hydrocarbon profiles corroborated our behavioural analysis that nurses from distinct colonies overlap greater amount of cuticular hydrocarbons.     

白蚁表皮碳氢化合物研究进展

近年来, 固相微萃取等现代技术的使用显著促进了白蚁表皮碳氢化合物研究的开展。至今, 已有约29种白蚁的表皮碳氢化合物组分得到鉴定, 分属于木白蚁科、 鼻白蚁科、 原白蚁科和白蚁科, 其组分主要为正烷烃、 含有不同数量甲基的支链烷烃及少量烯烃。白蚁表皮碳氢化合物不仅具有一定的科、 属特异性, 大多数种类还具备特有组分, 表明其可作为种间识别的指标。表皮碳氢化合物组分在种内个体识别方面的作用, 在低等白蚁中多获得了支持性结果, 但也有研究认为在这些种类中表皮碳氢化合物不是种内个体识别（同巢个体识别）的唯一指标。发现其与品级分化的相关是近年来白蚁表皮碳氢化合物研究的重要进展。有些种类表皮碳氢化合物的年消长与生殖蚁的分化有关; 而另一些种类生殖蚁含有表皮碳氢化合物特有组分, 其含量与生殖蚁的生殖状态有关, 提示其可能在品级分化中发挥重要作用。作为研究白蚁品级分化和维持机理的新方向, 表皮碳氢化合物值得进一步研究探索。     

Ontogeny of hydrocarbon profiles in the ant Aphaenogaster senilis and effects of social isolation

In ants, cuticular hydrocarbons are used for nestmate recognition; they are stored in the postpharyngeal gland and shared among the individuals. Newly emerged ants have a very small quantity of hydrocarbons. We studied the ontogeny of the hydrocarbon profile in Aphaenogaster senilis. The total quantities of both cuticular and postpharyngeal gland (PPG) hydrocarbons increased with age from 0 to 20 days after emergence and then stabilised. These quantities are correlated with the development of the ovary. Under individual social isolation, cuticular hydrocarbons increased as normal, but the total quantity of PPG hydrocarbons never increased from the initial low level. This effect of social isolation on the PPG hydrocarbon level indicates the importance of hydrocarbon transfer between nestmates through the PPG and lends support to the gestalt model of nestmate recognition. To cite this article: K. Ichinose, A. Lenoir, C. R. Biologies 332 (2009).     

The cuticular hydrocarbons profiles in the stingless bee Melipona marginata reflect task-related differences

Members of social insect colonies employ a large variety of chemical signals during their life. Of these, cuticular hydrocarbons are of primary importance for social insects since they allow for the recognition of conspecifics, nestmates and even members of different castes. The objectives of this study were (1) to characterize the variation of the chemical profiles among workers of the stingless bee Melipona marginata, and (2) to investigate the dependence of the chemical profiles on the age and on the behavior of the studied individuals. The results showed that cuticular hydrocarbon profiles of workers were composed of alkanes, alkenes and alkadienes that varied quantitatively and qualitatively according to function of workers in the colony.     

Distribution and variability of cuticular hydrocarbons within the Coleoptera

The cuticular lipids of 37 species of beetles (Coleoptera), 12 of which belong to the suborder Adephaga and 25 to the suborder Polyphaga, were analysed. They were found to consist almost exclusively of hydrocarbons. GLC and MS analyses revealed distinct patterns of hydrocarbons comprising alkanes, alkenes and alkadienes, 2-, 3- and internally branched monomethylalkanes as well as dimethyl-branched alkanes. These patterns depend on the species but exhibit conformity at the super-family or family level. The utility of cuticular hydrocarbons for coleopterous chemosystematics is discussed.     

The function of the post-pharyngeal glands of the red imported fire ant, Solenopsis invicta buren

Using radiolabelled triglycerides and fatty acids we have shown that these 2 lipids are absorbed into the haemolymph of the imported fire ant, Solenopsis invicta Buren from the post-pharyngeal gland. The post-pharyngeal glands attain their greatest weight and contain the highest hexane extractable lipid in establishing queens which have just reared the first minum brood. The lipid content of the digestive system is greatest in queens initiating a mating flight with the majority of the lipid contained in the crop. During colony establishment by the queen the lipid content of the crop moves forward, some is fed to the developing larvae and some moves into the post-pharyngeal gland. The hexane extractable lipid from the postpharyngeal gland of newly mated queens consists of hydrocarbons, sterols. tri-, di-, and monoglycerides and free fatty acids with a trace of wax esters.Excision of the post-pharyngeal glands from mated established queens causes no noticeable change in their behaviour or the behaviour they elicit from the remainder of the colony. However, post-pharyngeal glandectomized females lost weight and died in ca. 2 months although their crop and midgut contained food. The post-pharyngeal glands therefore appear to function in much the same way as a gastric caecum.     

Adoption of lycaenid Niphanda fusca (Lepidoptera: Lycaenidae) caterpillars by the host ant Camponotus japonicus (Hymenoptera: Formicidae)

Caterpillars of the parasitic lycaenid butterfly are often adopted by host ants. It has been proposed that this adoption occurs because the caterpillars mimic the cuticular hydrocarbons of the host ant. This study aimed to examine whether caterpillars of the Japanese lycaenid butterfly Niphanda fusca induce adoption by mimicking their host ant Camponotus japonicus. Behavioral observations conducted in the laboratory showed that most second‐instar caterpillars were not adopted, whereas most third‐instar caterpillars were successfully adopted by host workers. A chemical comparison detected no characteristic differences in the cuticular hydrocarbon profiles between second‐ and third‐instar caterpillars. However, morphological features of the caterpillars differed between the second and third instars; third‐instar caterpillars developed exocrine glands (ant organs) such as tentacle organs and a dorsal nectary organ. These results suggest that multiple chemical signatures, not only cuticular hydrocarbons, may be important for invasion of the host ant nest.     

Tolerance requires the right smell: first evidence for interspecific selection on chemical recognition cues

The integument of insects is generally covered with cuticular hydrocarbons (CHC). They serve multiple functions, most prominent among them waterproofing and-especially among social insects-as communication signal. CHC profiles are incredibly diverse within and across species. However, the causes for CHC variation between species, and potential selection pressures that may shape CHC profiles, are hardly understood. Here, we investigated potential selection pressures on ant CHC. We tested the hypotheses that living in association with another species (e.g., parabiosis), and the climate of the ant's habitat, affect CHC composition. We conducted a large-scale comparison of 37 Camponotus species from five continents. Our results demonstrate that closely associated ant species possess significantly longer hydrocarbons and higher proportions of methylbranched alkenes and alkadienes than non- or loosely associated species. In contrast, climatic factors had no effects. This study shows that the need to be tolerated by another species greatly affects CHC profiles.     

Spatiotemporal patterns of intraspecific aggression in the invasive Argentine ant

The Argentine ant, Linepithema humile, is a widespread invasive species characterized by reduced intraspecific aggression within introduced populations. To illuminate the mechanisms underlying nestmate recognition in Argentine ants, we studied the spatial and temporal fidelity of intraspecific aggression in an introduced population of Argentine ants within which intraspecific aggression does occur. We quantified variation in the presence or absence of intraspecific aggression among nests over time both in the field and under controlled laboratory conditions to gain insight into the role of environmental factors as determinants of nestmate discriminatory ability. In addition, we compared levels of intraspecific aggression between nest pairs to the similarity of their cuticular hydrocarbons to determine the potential role of these compounds as labels for nestmate discrimination. In both field and laboratory comparisons, nest pairs behaved in a consistent manner throughout the course of the experiment: pairs that fought did so for an entire year, and pairs that did not fight remained nonaggressive. Moreover, we found a negative relationship between cuticular hydrocarbon similarity and the degree of aggression between nests, suggesting that these hydrocarbons play a role in nestmate discriminatory ability. In contrast to the prevailing pattern, ants from one site showed a marked change in behaviour during the course of this study. A concomitant change was also seen in the cuticular hydrocarbon profiles of ants from this site. Copyright 2002 The Association for the Study of Animal Behaviour. Published by Elsevier Science Ltd. All rights reserved.     

Myrmecophilous aphids produce cuticular hydrocarbons that resemble those of their tending ants

Aphid-tending ants protect aphids from natural enemies and collect honeydew secreted by the aphids. However, ants also often prey on the aphids they attend. Aphids, therefore, like social parasites of ants, may well have evolved chemical mimicry as an anti-predation strategy. In this study, we aimed to determine whether the aphid Stomaphis yanonis actively produces cuticular hydrocarbons (CHCs) that resemble those of the tending ant Lasius fuji. In the wild, ants put their CHCs on the aphids that they are tending, so in this study we analyzed “ant-free” aphids. Mature aphids that exuviated in the absence of ant attendance had almost all of the hydrocarbon components that the ants’ CHCs had. Moreover, hydrocarbons artificially applied to the aphids’ body surface were lost by exuviation. Taken together, these findings indicate that mature aphids actively produced ant-like CHCs, and they constitute the first documentation of a chemical resemblance between aphids and ants in a specific aphid–ant association.     

Hydrocarbon site of synthesis and circulation in the desert ant Cataglyphis niger

Chemical analyses revealed that in Cataglyphis niger both the hemolymph and the crop contain the same hydrocarbons that are found in the postpharyngeal gland (PPG). On the cuticle, on the other hand, alkanes, and in particular nonacosane, were more abundant than in the PPG. Studies of their biosynthesis in vivo, using intact ants, revealed the presence of newly synthesized hydrocarbons in both the PPG and the crop. In decapitated ants (in the absence of the PPG), however, the crop did not contain any newly synthesized hydrocarbons, indicating the PPG as the major source of crop hydrocarbons. The fat body, as demonstrated by in vitro studies, is the major tissue that biosynthesizes hydrocarbons. The PPG failed to do so, but showed good de novo biosynthesis of other lipid constituents. The large amount of hydrocarbons in the crop suggests that the alimentary canal may serve as an outlet for the overflow of PPG hydrocarbons, or as a route for the directed clearance of hydrocarbons from the PPG.These results confirm and enlarge the model proposed for hydrocarbon circulation in C. niger. They are synthesized by the fat body, released to the hemolymph and transported to the cuticle and the PPG. The PPG hydrocarbons are applied to the cuticle by self-grooming, but can also be cleared via the alimentary canal. Partial emptying of the PPG may facilitate the admixing of recognition cues that the ant may acquire from nestmates by trophallaxis. The reason for the dissimilarity in hydrocarbon composition between the PPG and the cuticle is not yet clear; it may be due to secretions from additional glands, or reflect deviant hydrocarbon transport mechanisms between the PPG and the cuticle.     

Functional morphology of the postpharyngeal gland of queens and workers of the ant Monomorium pharaonis (L.)

Eelen D., Børgesen L.W. and Billen J. 2006. Functional morphology of the postpharyngeal gland of queens and workers of the ant Monomorium pharaonis (L.). —Acta Zoologica (Stockholm) 87 : 101–111 The postpharyngeal gland (PPG) is unique to ants and is the largest exocrine gland in their head. In queens of the pharaoh's ant, Monomorium pharaonis, the gland contains approximately 15 finger‐like epithelial extensions on each side and opens dorsolaterally in the posterior pharynx. In these ants the PPG morphology varies considerably according to age and mating status. The epithelial thickness increases with age and reaches a maximum at 3 weeks in both virgin and mated queens. A considerable expansion of the lumen diameter occurs in both groups between 4 and 7 days. Virgin queens release their secretion into the gland lumen from an age of 7 days, whereas mated queens accumulate large amounts of secretion in their epithelium. The increasing epithelial thickness, together with the increasing lumen diameter, the presence of numerous inclusions in the epithelium and the release of secretion, are indicative for increasing gland activity. The gland ultrastructure indicates involvement in lipid metabolism and de novo synthesis of lipids. The PPG of workers consists of 12 finger‐like tubes at each side. There is a significant difference in epithelial thickness between nurses and repletes and between nurses and foragers. We suggest the PPG serves different purposes in pharaoh's ants: it is likely that the PPG of workers and virgin queens is used to feed larvae. In mated queens the gland probably plays a role in providing the queen with nutritious oils for egg production. The PPG may also function in signalling species nestmate and caste identity, as well as in the reproductive capacity of the queens.     

Behavioral Activity of Hydrocarbons Emitted by Honeybee Waggle Dancers

Waggle-dancing honeybee foragers emit four hydrocarbons that have been shown to stimulate colony foraging by reactivating experienced foragers and increasing the number of recruitment dances. These hydrocarbons, the alkanes tricosane and pentacosane, and the alkenes (Z)-9-tricosene and (Z)-9-pentacosene, are part of the array of social insects cuticular lipids which have been well studied in the context of nestmate recognition. This study seeks to determine which of the dance hydrocarbons produce the behavioral responses of forager bees by using a binary choice behavioral assay for attraction or repulsion to the volatile phase of the dance compounds. We found no significant deviation from random choice for single dance compounds and pairs of compounds, but bees were significantly attracted to a mixture of the three compounds (Z)-9-tricosene, tricosane, and pentacosane. These results suggest synergy among the waggle-dance hydrocarbons, which was unexpected based on previous research where, in the context of nestmate recognition, alkenes have been shown to play a key role in eliciting behavioral responses. Synergy among the waggle-dance hydrocarbons may provide specificity that facilitates adaptive, context-specific behavioral responses to this subset of cuticular hydrocarbons.     

Ants recognize foes and not friends

Discriminating among individuals and rejecting non-group members is essential for the evolution and stability of animal societies. Ants are good models for studying recognition mechanisms, because they are typically very efficient in discriminating ‘friends’ (nest-mates) from ‘foes’ (non-nest-mates). Recognition in ants involves multicomponent cues encoded in cuticular hydrocarbon profiles. Here, we tested whether workers of the carpenter ant Camponotus herculeanus use the presence and/or absence of cuticular hydrocarbons to discriminate between nest-mates and non-nest-mates. We supplemented the cuticular profile with synthetic hydrocarbons mixed to liquid food and then assessed behavioural responses using two different bioassays. Our results show that (i) the presence, but not the absence, of an additional hydrocarbon elicited aggression and that (ii) among the three classes of hydrocarbons tested (unbranched, mono-methylated and dimethylated alkanes; for mono-methylated alkanes, we present a new synthetic pathway), only the dimethylated alkane was effective in eliciting aggression. Our results suggest that carpenter ants use a fundamentally different mechanism for nest-mate recognition than previously thought. They do not specifically recognize nest-mates, but rather recognize and reject non-nest-mates bearing odour cues that are novel to their own colony cuticular hydrocarbon profile. This begs for a reappraisal of the mechanisms underlying recognition systems in social insects.