The evolution of symmetrical snapping in termite soldiers need not lead to reduced chemical defence

Termite soldiers use a multitude of defensive strategies, often combining mechanical weapons with defensive chemicals secreted from their frontal gland. In higher termites (Termitidae), both these weapons are situated in the head of the soldiers. Their simultaneous occurrence is supposed to be subjected to energetic and spatial constraints and the resulting trade‐off often leads to a full development of only one of the weapons and reduction of the other. Mandibular snapping represents an extreme and efficient anatomical adaptation, allowing the soldier to knock out arthropod enemies with a violent strike of elongated mandibles. The head of snapping soldiers harbours massive adductor muscles while the frontal gland is reported to be reduced and the chemical defence absent. Here we show that the symmetrical snapping soldiers of the Neotropical termite Cavitermes tuberosus possess a well‐developed frontal gland situated in the frontal projection on their head. The gland produces a blend of unbranched alkenes and alkadienes combined with three diterpene hydrocarbons, derived from a novel bicyclic hydrocarbon skeleton. We characterized the molecular structure of the most abundant of these diterpenes and proposed for it a trivial name, cavitene. We conclude that the evolution of the mandibular snapping has not necessarily been accompanied by the reduction or loss of chemical defensive adaptations and that the two defensive modes are not mutually incompatible. © 2015 The Linnean Society of London, Biological Journal of the Linnean Society, 2015, ●● , ●●–●●.     

Worker aggression of ant Lasius japonicus enhanced by termite soldier–specific secretion as an alarm pheromone of Reticulitermes speratus

The subterranean termite Reticulitermes speratus usually nests in rotten wood trunks, which may also be occupied by the Japanese garden ant Lasius japonicus. Few battles were observed between them under ordinary circumstances because they inhabit separate nesting sites. However, once the termite nesting sites were artificially broken, the ant workers invaded and hunted the termites, although the termite soldiers fought against the ants. This study aims to confirm intra‐ and inter‐specific chemical interactions between the termite and ant. Solid phase microextraction–gas chromatograph (SPME‐GC) analyses revealed that R. speratus soldiers secreted caste‐specific sesquiterpene hydrocarbon when they were irritated. Both the hexane extract of the soldiers and its hydrocarbon fraction, as well as the crushed soldier bodies, attracted the soldiers but dispersed the workers when presented on the trails. We also confirmed that the soldier chemicals enhanced aggressiveness of L. japonicus, which rushed around the odor sources and hunted any termites that were present. These findings suggest that: (i) the soldier–specific secretion might serve as an alarm pheromone in termite chemical communication, in which components recruit soldiers and also warn the other colony members away; and (ii) termite communication is eavesdropped on by L. japonicus workers to locate and hunt the termites.     

蝽类昆虫的臭腺

臭腺是蝽类昆虫的重要特征之一 ,几乎所有的蝽类昆虫都具有臭腺 ;本文简单介绍了蝽类臭腺的形态结构、发育和臭腺分泌物的组成及其生物学作用等 ,其中对猎蝽科昆虫的相关介绍较为详细。     

Expression and function of a limb‐patterning gene Distal‐less in the soldier‐specific morphogenesis in the nasute termite Nasutitermes takasagoensis

One of the major foci in evolutionary developmental biology is to understand developmental mechanisms that underlie the acquisition of morphological novelties. Termite soldiers, the highly specialized defensive caste, show exaggerated species‐specific morphologies, mostly enlarged mandibles. Soldiers of the subfamily Nasutitermitinae (Termitidae), however, possess a novel structure for defense in their heads, that is a horn‐like frontal projection (nasus) from which defensive chemicals are discharged. Just prior to the molt into presoldiers (the preceding stage to soldiers) from workers, a nasus disc, or a nasus primordium, is observed under the worker head cuticle. In order to understand the developmental underpinnings of this evolutionarily novel structure, the role of a homeobox gene Distal‐less (Dll) during nasus development was examined in this study, using a nasute termite Nasutitermes takasagoensis. Histological observations showed that complex developmental processes comprising epidermal evagination and invagination through changes in cell shape and cell proliferation formed the projection and the gland. Immunohistochemistry showed that Dll was localized in the developing nasus disc, but not in the frontal‐gland primordium. Consistent with this finding, Dll RNA interference only repressed nasus growth not the frontal‐gland formation. Taken together, the co‐option of Dll is suggested to contribute to the acquisition of a novel defensive structure in a termite lineage, coupled with the acquisition of adaptive defensive behaviors.     

Structure and function of defensive glands in soldiers of Glossotermes oculatus (Isoptera: Serritermitidae)

The soldier caste represents the most conspicuous realization of termite eusociality, characterized by an extreme anatomical, behavioural, and physiological specialization. Numerous strategies have evolved in soldiers, including extreme adaptations such as self‐sacrifice by autothysis. In the present study, we investigated the structure and function of defensive glands in Glossotermes oculatus soldiers aiming to understand their use in combat. Three glands are involved in defence: labral, frontal, and labial glands. Mandibles are used to bite the enemy, whereas the secretions of labral and labial glands are discharged into the wound. A striking characteristic of G. oculatus is the lack of the frontal pore; the secretion of the frontal gland is discharged by a rupture of the body wall. We hypothesized that this self‐sacrifice is an efficient way of blocking a gallery under attack. A similar development of the frontal gland occurs in Serritermes serrifer, which supports the close relationship between the two genera inferred from morphological and genetic analyses. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 99 , 839–848.     

Comparative Study of the Labial Gland Secretion in Termites (Isoptera)

Labial glands are present in all castes and developmental stages of all termite species. In workers, their secretion contains a food-marking pheromone and digestive enzymes, while soldier secretion plays a defensive role. However, these functions were studied only in a limited set of species, and do not allow drawing general conclusions. Hence, we have investigated the chemical composition of the labial gland extracts from soldiers and workers in 15 termite species belonging to 6 families using an integrative approach based on proteomic and small-molecule profiling. We confirmed the presence of hydroquinone and cellulase in the labial glands of workers, and we identified new toxic compounds in soldiers and workers of several species. Our results highlight the dual role of labial gland secretion, i.e. the defensive role in soldiers and workers of several termite species, and the digestive function in workers.     

白蚁诱食信息素研究进展

白蚁为社会性昆虫,其组织结构和联系方式主要由白蚁外分泌腺产生的起诱导和调节白蚁行为反应作用的信息素来获得。由白蚁下唇腺产生的诱食信息素,能够在白蚁巢体的群体性食物采集中诱使取食白蚁形成聚集,并且取食食物的相同位置,从而提高白蚁巢体采集食物的效率。目前,已确定对苯二酚为白蚁诱食信息素,且认为整个等翅目昆虫都产生和使用对苯二酚作为诱食信息素,与分类地位和生物学特性无关。该文概述了白蚁诱食信息素的分泌器官、种特异性、生物学意义、生物合成途径及其在白蚁防治中的应用等方面的研究进展。     

How do predators cope with chemically defended foods?

Many prey species (including plants) deter predators with defensive chemicals. These defensive chemicals act by rendering the prey's tissues noxious, toxic, or both. Here, I explore how predators cope with the presence of these chemicals in their diet. First, I describe the chemosensory mechanisms by which predators (including herbivores) detect defensive chemicals. Second, I review the mechanisms by which predators either avoid or tolerate defensive chemicals in prey. Third, I examine how effectively free-ranging predators can overcome the chemical defenses of prey. The available evidence indicates that predators have mixed success overcoming these defenses. This conclusion is based on reports of free-ranging predators rejecting unpalatable but harmless prey, or voluntarily ingesting toxic prey.     

Responses of Coptotermes formosanus and Reticulitermes flavipes (Isoptera: Rhinotermitidae) to three types of wood rot fungi cultured on different substrates

This study examined the responses of two termite species, the Formosan subterranean termite, Coptotermes formosanus Shiraki, and the eastern subterranean termite, Reticulitermes flavipes (Kollar), to three types of wood decay fungi: a brown rot fungus, Gloeophyllum trabeum (Persoon: Fries) Murrill; a white rot fungus, Phanerochaete chrysosporium Burdsall; and a litter rot fungus, Marasmiellus troyanus (Murrill) Singer. We also examined the responses of termites to these three types of fungi grown on different substrates. For all three fungal species, both termite species showed a strong preference for fungus-infected sawdust over uninfected sawdust. In choice tests, both termite species preferred sawdust infected with either M. troyanus or P. chrysosporium over G. trabeum. However, termites did not show any preference for fungus-infected potato dextrose agar over uninfected potato dextrose agar. Tunneling activity of C. formosanus was greater in sand treated with methanol extracts of fungus-infected sawdust than in sand treated with extracts of uninfected sawdust. Because chemicals in the fungal extracts caused termites to tunnel further into treated sand than untreated sand, these chemicals could potentially be used to direct termite foraging toward bait stations in the field.     

Exploring the Potential for Actinobacteria as Defensive Symbionts in Fungus-Growing Termites

In fungus-growing termites, fungi of the subgenus Pseudoxylaria threaten colony health through substrate competition with the termite fungus (Termitomyces). The potential mechanisms with which termites suppress Pseudoxylaria have remained unknown. Here we explore if Actinobacteria potentially play a role as defensive symbionts against Pseudoxylaria in fungus-growing termites. We sampled for Actinobacteria from 30 fungus-growing termite colonies, spanning the three main termite genera and two geographically distant sites. Our isolations yielded 360 Actinobacteria, from which we selected subsets for morphological (288 isolates, grouped in 44 morphotypes) and for 16S rRNA (35 isolates, spanning the majority of morphotypes) characterisation. Actinobacteria were found throughout all sampled nests and colony parts and, phylogenetically, they are interspersed with Actinobacteria from origins other than fungus-growing termites, indicating lack of specificity. Antibiotic-activity screening of 288 isolates against the fungal cultivar and competitor revealed that most of the Actinobacteria-produced molecules with antifungal activity. A more detailed bioassay on 53 isolates, to test the specificity of antibiotics, showed that many Actinobacteria inhibit both Pseudoxylaria and Termitomyces, and that the cultivar fungus generally is more susceptible to inhibition than the competitor. This suggests that either defensive symbionts are not present in the system or that they, if present, represent a subset of the community isolated. If so, the antibiotics must be used in a targeted fashion, being applied to specific areas by the termites. We describe the first discovery of an assembly of antibiotic-producing Actinobacteria occurring in fungus-growing termite nests. However, due to the diversity found, and the lack of both phylogenetic and bioactivity specificity, further work is necessary for a better understanding of the putative role of antibiotic-producing bacteria in the fungus-growing termite mutualistic system.     

白蚁信息素研究进展

白蚁是最古老的社会性昆虫, 其社会性的维持需要信息素的相互作用。本文回顾了近年来国内外白蚁信息素研究的最新进展, 内容涉及白蚁踪迹信息素、 性信息素、 告警信息素和促食信息素的功能、 化学成分及产生信息素的外分泌腺。白蚁分泌信息素的腺体主要有背板腺、 腹板腺、 后腹板腺、 额腺和唾腺。绝大多数白蚁信息素是挥发性物质。白蚁在化学通讯上存在节俭策略, 即同一种化合物由不同的白蚁种类的不同外分泌腺分泌, 可具有不同的功能。总结了各类信息素在白蚁物种间、 同一物种的品级间和性别间的异同和作用方式, 强调了白蚁信息素的反应阈值、 最佳浓度、 有效期和物种特异性对其功能的影响。目前对白蚁信息素的研究尚处于起步阶段, 其研究成果对等翅目系统发育研究和白蚁防治具有重要的意义。文章最后展望了白蚁信息素在白蚁防治上的应用前景。     

The nasus gland: A new gland in soldiers of Angularitermes (Termitidae,Nasutitermitinae)

Termites have developed many exocrine glands, generally dedicated to defence or communication. Although a few of these glands occur in all termite species, or represent synapomorphies of larger clades, others are morphological innovations of a single species, or a few related species. Here, we describe the nasus gland, a new gland occurring at the base of the nasus of Angularitermes soldiers. The nasus gland is composed of class 1, 2, and 3 secretory cells, a rare combination that is only shared by the sternal and tergal glands of some termites and cockroaches. The ultrastructural observations suggest that the secretion is produced by class 2 and 3 secretory cells, and released mostly by class 3 cells. The base of the nasus has a rough appearance due to numerous pits bearing openings of canals conducting the secretion from class 3 secretory cells to the exterior. We tentatively assign a defensive function to the nasus gland, although further research is needed to confirm this function. Although the gland is described only from species of Angularitermes, other genera of Nasutitermitinae also present a rough nasus base, suggesting the presence of a similar, possibly homologous, gland.     

The clypeal gland: A new exocrine gland in termite imagoes (Isoptera: Serritermitidae,Rhinotermitidae, Termitidae)

Social insects possess a rich set of exocrine organs producing diverse pheromones and defensive compounds. This is especially true for termite imagoes, which are equipped with several glands producing, among others, sex pheromones and defensive compounds protecting imagoes during the dispersal flight and colony foundation. Here, we describe the clypeal gland, a new termite exocrine organ occurring in the labro-clypeal region of imagoes of most Rhinotermitidae, Serritermitidae and Termitidae species. The clypeal gland of Coptotermes testaceus consists of class 1 (modified epidermal cell) and class 3 (bicellular gland unit) secretory cells. Ultrastructural features suggest that the gland secretes volatile compounds and proteins, probably after starting the reproduction. One peculiar feature of the gland is the presence of multiple secretory canals in a single canal cell, a feature never observed before in other insect glands. Although the function of the gland remains unknown, we hypothesize that it could produce secretion signalling the presence of functional reproductives or their need to be fed.     

High-level expression of the Geranylgeranyl diphosphate synthase gene in the frontal gland of soldiers in Reticulitermes speratus (Isoptera: Rhinotermitidae)

Defensive strategies of termite soldiers are roughly classified as either mechanical, using mandibles and/or the whole head, or chemical, using frontal gland secretion. Soldiers of the genus Nasutitermes (Termitidae, Nasutitermitinae), which is one of the most derived termite genera, use only chemical defenses, and diterpene defensive secretions were suggested to be synthesized through geranylgeranyl diphosphate (GGPP). On the other hand, soldiers of the genus Reticulitermes (Rhinotermitidae, Heterotermitinae) mainly use mechanical defenses, but also use supplementary chemical defenses involving frontal gland secretions, including diterpene alcohol. In this study, to confirm whether the GGPP is used for diterpene synthesis in a representative of an earlier-branching termite lineage, the GGPP synthase gene (RsGGPPS) was identified in the rhinotermitid Reticulitermes speratus (Kolbe). The relative expression level of RsGGPPS in soldiers was three-fold higher than in workers. Furthermore, RsGGPPS gene expression was detected in epithelial class 1 gland cells around the frontal-gland reservoir. Although GGPP is used for various essential cellular roles in animals, RsGGPPS is suggested to be used not only for these essential roles but also for diterpene synthesis in order to produce defensive secretions. Chemical structures of the diterpene identified from Reticulitermes and Nasutitermes are extremely different from each other, and the two genera are phylogenetically distant from each other. Thus, these two lineages may have independently acquired the abilities of diterpene synthesis from GGPP.     

Characterization of chemical defenses in ranid tadpoles against a fish predator

Tadpoles of some ranid species appear to possess chemical defenses against fish predators, but the chemicals have not been characterized. Here, we evaluated the vulnerability of three Japanese anuran tadpole species (Glandirana rugosa, Pelophylax nigromaculatus, and Hyla japonica) to a fish (Gnathopogon elongatus elongatus) and analyzed the defensive chemicals extracted from the unpalatable tadpoles. Additionally, we examined the defensive behavior of unpalatable tadpoles in response to fish chemical cues. The fish rejected both G. rugosa (83%) and P. nigromaculatus (48%), but not H. japonica (0%). Many of the rejected tadpoles survived (60–80%). Possible defensive chemicals were extracted by methanol from the skin of G. rugosa, but were not identifiable by gas chromatography–mass spectrometry because of small quantities. The chemicals have high polarity and non-volatility. When exposed to fish chemical cues, P. nigromaculatus decreased activity presumably as a defensive behavior, but G. rugosa did not. We demonstrated the presence of chemical defenses in at least two of these species and revealed that G. rugosa releases more effective or greater amounts of defense chemicals than P. nigromaculatus with respect to this fish predator. The increased efficacy of chemical defenses may correlate with decreasing defensive behavior.     

The response of leaf resin to artificial herbivory in Eriodictyon californicum

Herbivore damage induces the production of defensive chemicals in many plant species. However, defensive chemicals sometimes have functions other than protection from herbivores, and these chemicals may respond to hervibory differentialy than those which are primarily defensive. A well-studied group of leaf constituents with multiple functions is the phenolic leaf resins, which protect leaves from herbivores, UV radiation, and possibly excess water loss. The effects of herbivory on phenolic leaf resins were investigated in the chapparral shrub Eriodictyon californicum by artificially damaging leaves during the growing season and subsequently measuring resin content and composition. We found that (i) resin content declined in leaves damaged by artificial herbivory; (ii) resin declined (at the P < 0.1 level) in undamaged leaves present on the same plant as those heavily damaged; and (iii) resin composition, as measured by the ratio of the major components, was unaffected by artificial herbivory.     

Behavioural and toxic effects of termite defensive secretions on ants

ABSTRACT. The toxicity and biological activity of the defensive secretions of ten species of neotropical termites were examined by bioassay on two species of predatory ant. Pseudomyrmex termitarius (F. Smith) (Pseudomyrmecinae) was more susceptible to the effects of the secretions than Ectatomma sp. (Ponerinae). The bioassay results show a progression in the nature of termite chemical weaponry and in the potency of defensive secretions. The tacky secretions used by Coptotermes and Ruptitermes are simply adhesive, entangling agents with no apparent toxic or pheromonal properties. The secretion of Syntermes calvus Emerson serves as a wound-active poison with little topical activity, while those of Armitermes spp. are repellent to ants and show activity as topical poisons. The secretions used by Nasutitermes spp. combine adhesive, entangling properties with the toxicity of a topically-active poison, and are effective also as ant-repellents.     

Plant chemical defense: monoterpenes and the growth-differentiation balance hypothesis

Recent studies of allocation to defensive chemicals in plants have provided insights into the ecological controls over plant defensive chemicals. Both developmental and ecological studies now suggest that we can understand the factors influencing allocation to defense by examining the relative availability of resources, external needs for chemical defense, and the internal demands for growth that plants face. These studies have also shed light on one of the more popular theories in plant evolutionary ecology, the growth-differentiation balance hypothesis of plant resource allocation.     

Interaction of pheromones during food exploitation by the termite Schedorhinotermes lamanianus

Abstract. Chemical signals from secretions of different exocrine glands modulate a variety of behavioural patterns in termite societies. These signals have multiple functions and may be interactive. During food exploitation workers of the African termite Schedorhinotermes lamanianus (Isoptera: Rhinotermitidae) employ, on foraging trails, the secretion from the sternal gland both for orientation and recruitment to a food source. The secretion from the labial gland, released onto the food by gnawing termites, stimulates additional workers to gnaw at the same site, thereby forming aggregations of gnawing termites. An interaction between these two pheromones during food exploitation is demonstrated for the first time. The volatile signal from the sternal gland inhibits in a dose-dependent manner the non-volatile, highly persistent, signal from the labial gland. The development of gnawing aggregations is inhibited and established ones are dissolved. Behavioural evidence for the perception of both the volatile signal from the sternal gland by olfactory neurones and of the non-volatile signal from the labial gland by gustatory neurones on the antennae is given. The interaction of the two pheromones as a basis for the development of distinct commuting and gnawing zones on the food source, and as a means for a dynamic regulation of food exploitation, is discussed.