Social Insect Pheromones: Their Chemistry and Function

Exocrine secretions of social insects are often characterizedby extraordinarily complex mixtures of natural products. Thus,chemical communication in social insects must be interpretedin terms of signals generated by multicomponent systems, theindividual constituents of which can affect the informationalcontent of the message. Alarm pheromones have been identified chiefly in three subfamiliesof ants and their distribution appears to be chemosystematicallysignificant. Myrmicine genera emphasize 3-alkanones as alarmreleasers, whereas methyl ketones, primarily of terpenoidalorigin, are widely utilized as alarm pheromones in the subfamilyDolichoderinae. Formicine species may employ formic acidas analarm pheromone in addition to the compounds produced in themandibular and Dufour's glands. The mandibular gland pheromonesare chiefly acyclic monoterpene aldehydes (e.g., citronellal)which are relatively low boiling compounds. Higher boiling n-alkanesare produced in the Dufour's glands and may serve as more persistentreleasers of alarm behavior. Alarm pheromones as well as thecaste-specific pheromones of male bees and ants, probably alsoserve as defensive products. In many cases it is likely thatpheromones were originally utilized as defensive compounds andtheir communicative function is a secondary development.     

Reduced cephalic labial glands in the male bumblebees of the subgenus Rhodobombus Dalla Torre (Hymenoptera: Apidae: Bombus Latreille)

Until now, all males of bumblebees are known to attract conspecific females by marking places with a chemical signal secreted by their cephalic labial gland. The specific combination of patrolling flight and scentmarking is of outmost importance to bumblebees as it is their main species specific recognition system. We report here the lack of that recognition system in species of the subgenus Rhodobombus by comparing the morphology and histology of the cephalic labial glands of Bombus (Rhodobombus) mesomelas with those of a well known species, B. (Bombus) terrestris (L.) The cephalic labial glands are much smaller in B. mesomelas than in other bumblebees species and most likely non-functional. This morphology is also observed in B. pomorum and B. brodmanni which also belong to the subgenus Rhodobombus. Our morphological observations are consistent with the chemical analyses of the secretions in B. mesomelas and B. pomorum which are very limited and of most unusual composition for a bumblebee. In addition, whereas other species are thought to use their barbae mandibularis to spread their secretion onto the substrate, these structures are absent in all Rhodobombus. All these observations would mean that the males of Rhodobombus do not attract females from far away by the use of their cephalic labial gland secretions.     

Analysis of the labial gland secretions of the male bumble bee Bombus perplexus Cresson (Hymenoptera: Apidae) from North America

The labial gland secretions from males of the bumble bee Bombus (Pyrobombus) perplexus Cresson were analysed by gas chromatography/mass spectrometry (GC/MS) in the electron impact and positive ion chemical ionization mode. The major compound of the complex mixture of alkenols, alkenals, fatty acids, hydrocarbons, wax type esters and steroids is 3,7,11,15-tetramethyl-2,6,10-hexadecatrien-1-ol (geranylcitronellol), considerable amounts of hexadecan-1-ol and Z-9-hexadecen-1-ol were also found. All alcohols were present as esters of the detected acids. In older samples both the acids and the alcohols sometimes could not be detected in the GC; therefore, the possibility to check the detected acid-alcohol pattern by interpreting the wax type ester peaks is very instructive. Moreover, the labial gland contains a rich mixture of mono- and di-unsaturated straight chain hydrocarbons. The similarity in composition of the labial glands of the North American B. (Pyrobombus) perplexus with the Eurasian species B. (Pyrobombus) hypnorum corroborates the assumption that the two species are conspecific. The likely supposition that the hydrocarbons could play an essential role in the chemical communication in bumble bees is discussed.     

Exocrine chemistry of the myrmicine ant Zacryptocerus pusillus (Hymenoptera: Formicidae)

Minor workers of the ant Zacryptocerus pusillus have unusual exocrine secretions in both their mandibular and Dufour glands. The mandibular glands contain a 3:1 mixture of 4-heptanone and 4-heptanol, a mixture found only in the related species Z. varians. The Dufour gland contains a mixture of 13 aldehydes from C9 to C18, not previously encountered in ant secretions. The venom glands gave variable results with only nonanal present consistently.     

Labial gland marking secretions of male Bombus lucorum bumblebees from Europe and China reveal two separate species: B. lucorum (Linnaeus 1761) and Bombus minshanicola (Bischoff 1936)

Differences in male bumblebee labial gland secretions can be used to separate species pairs. Cephalic labial gland secretions from male Bombus lucorum Linnaeus bumblebees from Europe, and male ‘B. lucorum’ bumblebees from China, were analyzed by gas chromatography/mass spectrometry (GC/MS). In the European B. lucorum L., ethyl tetradec-9-enoate was identified as the major compound (58% peak area), along with a complex mixture of straight-chain alkenols, acetates, hydrocarbons, and wax type esters. In contrast, the main component of the labial gland secretions of the Chinese ‘B. lucorum’, ethyl dodecanoate (31%), did not dominate the secretion, which additionally contained large amounts of 3,7,11-trimethyldodeca-6,10-dien-1-ol (=2,3-dihydrofarnesol, 24% peak area), ethyl octadec-9-enoate (15% peak area) and a mixture of acyclic diterpenes (alcohols, aldehydes, and acetates). Furthermore, in B. lucorum, 3,7,11-trimethyldodeca-6,10-dien-1-ol was only detected in trace amounts (0.05%) and ethyl octadec-9-enoate corresponded to only 0.8% of the mixture. These results indicate that ‘B. lucorum’ from China is a separate taxon from B. lucorum L. Further analysis revealed that ‘B. lucorum’ from China has been previously described as Bombus minshanicola Bischoff 1936 from Gansu/China. Differences in the chemical composition of male bumblebee labial gland secretions are discussed in comparison with other known bumblebee species pairs.     

Bumble bees alert to food with pheromone from tergal gland

Foragers of Bombus terrestris are able to alert their nestmates to the presence of food sources. It has been supposed that this happens at least partially through the distribution of a pheromone inside the nest. We substantiate this claim using a behavioral test in which an alerting signal is transmitted from one colony to another by long distance air transport, so excluding all other modalities of information exchange. We then investigated the source of the pheromone and were able to show that a hexane extract from tergites V-VII of bumble bee workers elicits higher activity, like a successful forager does. Extracts from other glands, such as the mandibular, labial, hypopharyngeal, and Dufour's gland as well as extracts from other parts of the cuticle had no effect. This suggests that bumble bees possess a pheromone-producing gland, similar to the Nasanov gland in honey bees. Indeed, an extract from the honey bee Nasanov gland also proved to alert bumble bee workers, suggesting a possible homology of the glands.     

Male labial gland secretions and mitochondrial DNA markers support species status of Bombus cryptarum and B. magnus (Hymenoptera, Apidae)

Summary. Spring queens of Bombus cryptarum and B. magnus from 2 localities in Brandenburg/Germany and Scotland/United Kingdom respectively were determined by morphological characteristics. The lateral border of the collare at the border of the pronotallobus or at the episternum proved to be an especially useful character. Artificial colonies were reared from safely determined spring queens and the cephalic part of the labial glands of males from these colonies were investigated by GC/MS. The investigation identified approximately 50 compounds, as a mixture of straight chain fatty acid derivatives (alcohols, esters and hydrocarbons). The labial secretions of B. cryptarum and B. magnus are significantly different. Mitochondrial cytochrome oxidase 1 (CO1) of two queens from each locality and species were sequenced. Each species from the different localities formed a cluster. Sequence divergence between B. cryptarum and B. magnus was about 30 base substitutions and approximately 0.04 in Tamura-Nei genetic distance. Bombus cryptarum and B. magnus were closer to each other than to B. lucorum and made the sister group in the topology of the tree. Both the CO1 sequences and the labial gland secretions of males of B. cryptarum from Brandenburg and of males from artificial colonies reared from safely determined spring queens from Scotland are identical. B. cryptarum has thus, for the first time, been identified as part of the British bumble bee fauna. The differences of both the labial gland secretions, used as species recognition signals, and the genetic differences established by sequencing CO1 confirm the morphological findings that B. cryptarum and B. magnus are distinct taxa which should be treated as distinct species.Received 25 March 2004; revised 13 June 2004; accepted 15 June 2004.     

Chemosensory proteins, major salivary factors in caterpillar mandibular glands

Research in the field of insect-host plant interactions has indicated that constituents of insect saliva play an important role in digestion and affect host chemical defense responses. However, most efforts have focused on studying the composition and function of regurgitant or saliva produced in the labial glands. Acknowledging the need for understanding the role of the mandibular glands in herbivory, we sought to make a qualitative and semi-quantitative comparison of soluble luminal protein fractions between mandibular and labial glands of Vanessa gonerilla butterfly larvae. Amylase and lysozyme were inspected as possible major enzymatic activities in the mandibular glands aiding in pre-digestion and antimicrobial defense. Although detected, neither of these enzymatic activities was prominent in the luminal protein preparation of a particular type of gland. Proteins isolated from the glands were identified by mass spectrometry and by searching an EST-library database generated for four other nymphalid butterfly species, in addition to the public NCBI database. The identified proteins were also quantified from the data using "Quanty", an in-house program. The proteomic analysis detected chemosensory proteins as the most abundant luminal proteins in the mandibular glands. In comparison to these proteins, the relative amounts of amylase and lysozyme were much lower in both gland types. Therefore, we speculate that the primary role of the mandibular glands in Lepidopteran larvae is chemoreception which may include the detection of microorganisms on plant surfaces, host plant recognition and communication with conspecifics.     

A stingless bee uses labial gland secretions for scent trail communication (<Emphasis Type="Italic">Trigona recursa</Emphasis> Smith 1863)

The pheromones used by several species of stingless bees for scent trail communication are generally assumed to be produced by the mandibular glands. Here we present strong evidence that in Trigona recursa these pheromones originate from the labial glands, which are well developed in the heads of foragers. Analysis of the behavior involved in scent marking shows that a bee extends her proboscis and rubs it over the substrate. A single scent marking event lasts for 0.59±0.21 s while the bee runs a stretch of 1.04±0.37 cm on a leaf. According to choice experiments the bees are attracted by a feeder baited with labial gland extract (84.2±6% of the bees choose this feeder) but repelled from a feeder baited with mandibular gland extract (only 27.5±13.1% of the bees choose this feeder). They do not discriminate between two clean feeders (49.6±3% of the bees at a feeder). 87±5.1% of bees already feeding leave the feeder after the application of mandibular gland extract whereas only 6.2±4.9% and 2.6±4% do so when labial gland extract or pure solvent was applied.     

The cephalic labial gland secretions of two socially parasitic bumblebees Bombus hyperboreus (Alpinobombus) and Bombus inexspectatus (Thoracobombus) question their inquiline strategy

Social parasitic Hymenopterans have evolved morphological, chemical, and behavioral adaptations to overcome the sophisticated recognition and defense systems of their social host to invade host nests and exploit their worker force. In bumblebees, social parasitism appeared in at least 3 subgenera independently: in the subgenus Psithyrus consisting entirely of parasitic species, in the subgenus Alpinobombus with Bombus hyperboreus, and in the subgenus Thoracobombus with B. inexspectatus. Cuckoo bumblebee males utilize species‐specific cephalic labial gland secretions for mating purposes that can impact their inquiline strategy. We performed cephalic labial gland secretions in B. hyperboreus, B. inexspectatus and their hosts. Males of both parasitic species exhibited high species specific levels of cephalic gland secretions, including different main compounds. Our results showed no chemical mimicry in the cephalic gland secretions between inquilines and their host and we did not identify the repellent compounds already known in other cuckoo bumblebees.     

Chemical composition of the poison apparatus secretions of the African weaver ant, Oecophylla longinoda, and their role in behaviour

ABSTRACT. Major workers of Oecophylla longinoda emit venom from the tip of the abdomen, as it is brought immediately above the head. The sources of the venom are (a) the poison gland, which contains formic acid, and (b) Dufour's gland, which contains hydrocarbons, including n-undecane and other n-alkanes, 4-tridecene, 8-heptadecene and 4, 7-heptadecadiene. The venom elicits a 'mass attack' response in other major workers. Formic acid and n-undecane presented together experimentally also evoke this response, the mixture being considerably more effective than either compound tested separately. These compounds act in combination with the mandibular gland secretions to form a complex alarm/defence system.     

Pheromonal activity and fine structure of the mandibular glands of honeybee drones (Apis mellifera L.) (Insecta,Hymenoptera, Apidae)

Experiments were conducted to determine the role of drone mandibular gland secretions in attracting flying drones and the effect of age on the secretory activity. Extracts of mandibular glands and of cephalic tissues were applied to cotton lures which were attached below balloons tethered at 8–12 m above the ground. Most flying drones were attracted to extracts of mandibular glands but a few were drawn to other cephalic tissues or to solvent controls. Histological and electron microscope studies showed that the structure of the tiny (0.12 mm long) mandibular gland varied according to age. Its secretory activity in 0–3-day old drones was evident from the abundant rough endoplasmic reticulum. At 7-days the glands were fully developed. After 9 days the glands were no longer active and showed an autolytic process; the product was stored in the gland lumen for further emission during drone mating flights.     

蜜蜂上颚腺及其分泌物研究进展

上颚腺是蜜蜂重要的外分泌腺体,其分泌物是维系蜂群社会性结构的重要物质。蜂王和工蜂上颚腺分泌物合成均以硬脂酸为合成前体,但在脂肪酸的β-氧化过程中表现出级型差异性,导致分泌物组分比例不同。蜂王上颚腺分泌物以9-羰基-2癸烯酸(9-ODA)为主,有吸引工蜂和雄蜂、抑制工蜂卵巢发育等作用;工蜂上颚腺分泌物以10-羟基-2癸烯酸(10-HDA)和10-羟基癸酸(10-HDAA)为主,是蜂王浆的重要组成部分。同时,这种具备典型级型差异的分泌物组成又具有级型间可塑性,在不同蜂种间也存在区别。近年来在转录水平和蛋白水平的一些研究进一步揭示了级型间差异的分子基础。针对蜜蜂上颚腺及其分泌物的研究在蜜蜂生物学、行为学和蜂产品质量控制等方面具有重要的意义。本文通过总结国内外相关研究进展,旨在为上颚腺分泌物的作用机制、生物合成机制等领域的进一步深入研究提供借鉴。     

Morphological and Histochemical Study of Cephalic Glands of Bothrops jararaca (Ophidia,Viperidae)

Morphological and histochemical studies of the cell types in the cephalic glands of Bothrops jararaca have been performed. It is concluded: 1) mucous cells are found in the salivary labial, accessory glands; mucous-serous cells are found in the salivary labial, accessory and Harderian glands; serous-mucous cells are found only in the venom gland; 2) neutral mucosubstances and protein were found in the salivary labial, venom, accessory and Harderian glands; 3) hyaluronic acid was detected in the Harderian gland; 4) of the to sulfated acid mucosubstances, only chondroitin sulfate B was detected in the salivary labial and accessory glands; 5) sialic acid was detected in the salivary labial, accessory and Harderian glands.     

Use of Dufour's gland secretion in nest defence and brood nutrition by hover wasps (Hymenoptera, Stenogastrinae)

Social wasps of the subfamily Stenogastrinae produce an abdominal secretion that is used in two distinct biological contexts. First, the secretion plays an important role in larval nutrition where it serves as a substrate in which food is placed by the adults for eventual consumption by the larvae. Second, in several species, females apply the same secretion to the substrate on which their nests are constructed, where it constitutes a sticky barrier that defends the immature brood from predation by ants. This paper describes for the first time ant guard construction behaviour of three species of stenogastrine wasps belonging to the genera Eustenogaster and Liostenogaster. The identification of compounds making up these secretions was also performed by gas chromatography-mass spectrometry. Ant guards and brood secretions were similar, with saturated and unsaturated long chain hydrocarbons and alcohols as major components. We further confirm that the glandular source of abdominal secretion is the Dufour's gland. This gland contains the same hydrocarbons, and in the same proportions as ant guards and brood secretion. We discuss the fundamental importance of Dufour's gland secretion in the social life of these wasps by comparing species with and without ant guards within the subfamily.     

Exocrine glands of the ant Myrmoteras iriodum

This paper describes the morphological characteristics of nine major exocrine glands in workers of the formicine ant Myrmoteras iriodum. The elongate mandibles reveal along their entire length a conspicuous intramandibular gland, which contains both class‐1 and class‐3 secretory cells. The secretory cells of the mandibular glands show a peculiar appearance, with a branched end apparatus, which is unusual for ants. The other major glands (pro‐ and postpharyngeal gland, infrabuccal cavity gland, labial gland, metapleural gland, venom gland and Dufour gland) show common features for formicine ants. The precise function of the glands could not yet be experimentally demonstrated, and to clarify this will depend on the availability of live material of these enigmatic ants in future.     

Ultrastructure of human labial salivary glands. 3. Myoepithelium and ducts

Myoepithelial cells were present between the basal lamina and the acinar secretory cells of human labial salivary glands. In form and disposition, they resembled myoepithelial cells in the major salivary glands. Many of these cells possessed single cilia on their upper surfaces. Such cilia occasionally extended into invaginations of the overlying secretory cell. The intercalated ducts were variable in occurrence. Their epithelium ranged from columnar to squamous, and showed few signs of secretory activity. Few intralobular ducts possessed basal striations. While mitochondria were abundant in non-striated cells, they were randomly disposed in both basal and apical cytoplasm, and the basal plasmalemma showed only occasional infoldings. The paucity of true striated ducts in labial salivary glands may be responsible for the high concentration of sodium and chloride in unstimulated labial gland salivary secretions.