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•Pimplinae antennal tips show peculiar pegs.•Pegs are not innervated, nor present associated glands.•Pegs are inserted through an inflexible socket.•Pegs are involved in the ...transmission of vibrations.
Pimplinae are parasitoids belonging to the family Ichneumonidae that attack and develops inside hidden host; female wasps evolved a peculiar host recognition strategy, that involves the use of self-produced vibrations which are transmitted through the antennae on the substrate and perceived back as an echo using the leg subgenual organ. In this study we investigated, using both scanning and transmission electron microscopy, the antennal tips of a few Pimplinae. In all the investigated species, the antennal tips present peculiar apical pegs with different shape and number, often defining a flattened sole devoid of other antennal structures, such as sensilla. These pegs are present in both sexes with different number and development, are inserted on the antennal wall through an inflexible socket and present a cuticular shaft with cuticle of different thickness. We never found the presence of sensory neurons or glandular epithelium associated with these pegs. Because of their peculiar morphological features, we hypothesize for the antennal apical pegs a role in the context of host searching behavior (in the case of the female through the vibrational sounding strategy), as well as during mating behavior.
We document the sensitivity to sinusoidal vibrations for chordotonal organs in the stick insect tibia (Sipyloidea sipylus). In the tibia, the scolopidial subgenual organ (~40 scolopidial sensilla), ...distal organ (~20 scolopidial sensilla), and distal tibial chordotonal organ (~7 scolopidial sensilla) are present. We study the sensitivity of tibial sensory organs in all leg pairs to vibration stimuli as sensory thresholds by recording summed action potentials from Nervus cruris in the femur. The tibia was stimulated with a minishaker delivering vibrational stimuli. Because different experimental procedures may affect the vibration sensitivity, we here analysed possible effects of different experimental conditions: (1) the stimulus direction delivered in either horizontal or vertical direction to the leg; (2) recording responses only from the subgenual organ complex after ablation of the distal tibial chordotonal organ, and (3) the attachment of the leg to the minishaker by plastilin, beeswax-colophony, or freely standing legs. The tibial scolopidial organs give summed responses to vibration stimuli with highest sensitivity between 500 and 1000Hz for all leg pairs. In the different experimental series, we find that (1) thresholds were influenced by stimulation direction with lower thresholds in response to vertical vibrations, (2) ablating the distal tibial chordotonal organ by cutting the distal-most tibia did not change the summed sensory thresholds significantly, and (3) the attachment material between legs and the minishaker (plastilin or beeswax-colophony mixture) did not significant influence the sensory thresholds against free-standing tarsi. The distal tibial chordotonal organ is a connective chordotonal organ attached to a tendon and is likely a proprioceptive organ. These results emphasise that vibrational thresholds are mainly direction-sensitive. Thus, the direction of stimulus delivery during electrophysiological recordings is relevant for comparisons of vibratory sensory thresholds.
The subgenual organ complex of stick insects has a unique neuroanatomical organisation with two elaborate chordotonal organs, the subgenual organ and the distal organ. These organs are present in all ...leg pairs and are already developed in newly hatched stick insects. The present study analyses for the first time the morphology of sensory organs in the subgenual organ complex for a membrane connecting the two sensory organs in newly hatched insects (Sipyloidea chlorotica (Audinet-Serville 1838)). The stick insect legs were analysed following hatching by axonal tracing and light microscopy. The subgenual organ complex in first juvenile instars shows the sensory organs and a thin membrane connecting the sensory organs resembling the morphology of adult animals. Rarely was this membrane not detected, where it is assumed as not developed during embryogenesis. The connection appears to influence the shape of the subgenual organ, with one end extending towards the distal organ as under tension. These findings are discussed for the following functional implications: (1) the physiological responses of the subgenual organ complex to mechanical stimuli after hatching, (2) the influence of the membrane on the displacement of the sensory organs, and (3) the connection between the subgenual organ and distal organ as a possible functional coupling.
Vibrations and sounds, collectively called vibroacoustics, play significant roles in intracolony communication in termites, social wasps, ants, and social bees. Modalities of vibroacoustic signal ...production include stridulation, gross body movements, wing movements, high-frequency muscle contractions without wing movements, and scraping mandibles or tapping body parts on resonant substrates. Vibroacoustic signals are perceived primarily via Johnston’s organs in the antennae and subgenual organs in the legs. Substrate vibrations predominate as vibroacoustic modalities, with only honey bees having been shown to be able to hear airborne sound. Vibroacoustic messages include alarm, recruitment, colony activation, larval provisioning cues, and food resource assessment. This review describes the modalities and their behavioral contexts rather than electrophysiological aspects, therefore placing emphasis on the adaptive roles of vibroacoustic communication. Although much vibroacoustics research has been done, numerous opportunities exist for continuations and new directions in vibroacoustics research.
Multiple mechanosensory organs form the subgenual organ complex in orthopteroid insects, located in the proximal tibia. In several Ensifera (Orthoptera), a small chordotonal organ, the so-called ...accessory organ, is the most posterior part of this sensory complex. In order to document the presence of this accessory organ among the Ensifera, the chordotonal sensilla and their innervation in the posterior tibia of two species of Jerusalem crickets (Stenopelmatidae: Stenopelmatus) is described. The sensory structures were stained by axonal tracing. Scolopidial sensilla occur in the posterior subgenual organ and the accessory organ in all leg pairs. The accessory organ contains 10–17 scolopidial sensilla. Both groups of sensilla are commonly spatially separated. However, in few cases neuronal fibres occurred between both organs. The two sensillum groups are considered as separate organs by the general spatial separation and innervation by different nerve branches. A functional role for mechanoreception is considered: since the accessory organ is located closely under the cuticle, sensilla may be suited to detect vibrations transferred over the leg's surface. This study extends the known taxa with an accessory organ, which occurs in several taxa of Ensifera. Comparative neuroanatomy thus suggests that the accessory organ may be conserved at least in Tettigoniidea.
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•The scolopodial accessory organ is documented in Jerusalem crickets Stenopelmatus.•As a unique feature, dendrites characteristically point in proximal direction.•In total, 4 chordotonal organs make up the subgenual organ complex in Stenopelmatus.•The neuroanatomical organisation is similar to related insects.•The accessory organ is likely conserved in Tettigoniidea.
Individuals of the insect order Mantophasmatodea use species-specific substrate vibration signals for mate recognition and location. In insects, substrate vibration is detected by mechanoreceptors in ...the legs, the scolopidial organs. In this study we give a first detailed overview of the structure, sensory sensitivity, and function of the leg scolopidial organs in two species of Mantophasmatodea and discuss their significance for vibrational communication. The structure and number of the organs are documented using light microscopy, SEM, and x-ray microtomography. Five scolopidial organs were found in each leg of male and female Mantophasmatodea: a femoral chordotonal organ, subgenual organ, tibial distal organ, tibio-tarsal scolopidial organ, and tarso-pretarsal scolopidial organ. The femoral chordotonal organ, consisting of two separate scoloparia, corresponds anatomically to the organ of a stonefly (
Nemoura variegata) while the subgenual organ complex resembles the very sensitive organs of the cockroach
Periplatena americana (Blattodea). Extracellular recordings from the leg nerve revealed that the leg scolopidial organs of Mantophasmatodea are very sensitive vibration receptors, especially for low-frequency vibrations. The dominant frequencies of the vibratory communication signals of Mantophasmatodea, acquired from an individual drumming on eight different substrates, fall in the frequency range where the scolopidial organs are most sensitive.
Entre as estratégias de comunicação utilizadas por animais o som é uma das mais importantes. Nos Hymenoptera destacam-se como órgãos auditivos o órgão subgenual, localizado na porção proximal da ...tíbia, e o órgão de Johnston, localizado no segundo segmento da antena. O objetivo do presente trabalho foi analisar morfologicamente tais estruturas em Agelaia pallipes (Olivier), Polybia paulista (Ihering) and Mischocyttarus cassununga (Ihering). As tíbias e antenas das três espécies foram retiradas e fixadas em glutaraldeído a 2% em tampão cocodilato de sódio 0,2 M, pH 7,4 durante 2h a 4ºC. Uma pós-fixação seguiu-se em tetróxido de ósmio a 2% no mesmo tampão. Nas espécies estudadas observaram-se semelhanças quanto à forma, localização e tamanho do órgão subgenual (OSG) e órgão de Johnston (OJ). O OSG apresentou a forma de um cone constituído por células nervosas presas à parede interna da tíbia em pontos laterais e opostos. Tal estrutura e sua localização parecem estratégias para a percepção de estímulos vibratórios decorrentes do substrato. No pedicelo das antenas das três espécies observaram-se células sensoriais do OJ, dispostas radialmente e terminando na conexão cuticular entre pedicelo e flagelo antenal. Esse arranjo permite ao OJ detectar estímulos vibratórios. Neste trabalho não foi analisada a possível relação entre a morfologia das estruturas sensoriais e o desenvolvimento da audição nas diferentes espécies estudadas.
Among the communication strategies used by the animals, the sound is one of the most important. Hymenoptera have as auditory organs, the subgenual organ (SGO) located in the tibia proximal portion, and the Johnston organ (JO) located in the second antenna segment. The subject of this work was to analyze the morphology of these structures in Agelaia pallipes (Olivier), Polybia paulista (Ihering) and Mischocyttarus cassununga (Ihering). The tibiae and antennae of the three species were dissected and fixed in 2% glutaraldhyde in 0, 2 M sodium cacodylate buffer, pH 7.4, during 2h, at 4ºC. Afterward, they were postfixed in 2% osmium tetroxide in the same buffer. We observed similarity in the shape, location and size of both, SGO and JO, among the studied species. SGO presented a conical shape formed by nervous cells fixed to the internal wall of the tibia on lateral and opposite points. Such structure and its location seem to constitute strategies to perceive vibratory stimulations originated from the substratum. In the pedicellum of the three species antenna, we observed JO sensorial cells, disposed in a radial form, ending in the cuticular connection between the pedicellum and the antennal flagella. This arrangement allows the JO to detect vibratory stimuli. In this work, a possible relation between morphology of the sensorial structures and the development of hearing in the different species was not analyzed.
Members of the Semaphorin family of glycoproteins play an important role in axonal pathfinding by functioning as inhibitory guidance cues. Here we provide evidence that a transmembrane form of ...Semaphorin (Semaphorin I), which is expressed by bands of epithelial cells in the developing grasshopper limb bud, functions as an attractive/permissive cue for the growth cones of the subgenual organ. In addition, we demonstrate that Semaphorin I is needed for initial axonal outgrowth from the subgenual organ. These results are consistent with an alternative function for a transmembrane form of Semaphorin and may explain the previously reported arrest of the proximal extension of the subgenual organ growth cones in the absence of the Ti1 pioneer pathway.
The subgenual organ of the honeybee (Apis mellifera) is suspended in a haemolymph channel in the tibia of each leg. When the leg is accelerated, inertia causes the haemolymph (and the subgenual ...organ) to lag behind the movement of the rest of the leg. The magnitude of this phase lag determines the displacement of the subgenual organ relative to the leg and to the proximal end of the organ, which is connected to the cuticle. Oscillations of the subgenual organ are visualised during vibration stimulation of the leg, by means of stroboscopic light. Video analysis provides fairly accurate values of the amplitude and phase of the oscillations, which are compared with the predictions of a model. The model comparison shows that the haemolymph channel can be described as an oscillating fluid-filled tube occluded by an elastic structure (probably the subgenual organ). The mechanical properties of the subgenual organ and haemolymph channel resemble those of an overdamped mass-spring system. A comparison of the threshold curve of the subgenual organ determined using electrophysiology with that predicted by the oscillating tube model suggests that the sensory cells respond to displacements of the organ relative to the leg.
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