Morfologia de estruturas sensoriais em pernas e antenas de Agelaia pallipes (Olivier), Polybia paulista (Ihering) e Mischocyttarus cassununga (Ihering) (Hymenoptera: Vespidae)

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Abstract

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.

Translated abstract

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.

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The structure and function of auditory chordotonal organs in insects.

Jayne Yack (2004)

Insects are capable of detecting a broad range of acoustic signals transmitted through air, water, or solids. Auditory sensory organs are morphologically diverse with respect to their body location, accessory structures, and number of sensilla, but remarkably uniform in that most are innervated by chordotonal organs. Chordotonal organs are structurally complex Type I mechanoreceptors that are distributed throughout the insect body and function to detect a wide range of mechanical stimuli, from gross motor movements to air-borne sounds. At present, little is known about how chordotonal organs in general function to convert mechanical stimuli to nerve impulses, and our limited understanding of this process represents one of the major challenges to the study of insect auditory systems today. This report reviews the literature on chordotonal organs innervating insect ears, with the broad intention of uncovering some common structural specializations of peripheral auditory systems, and identifying new avenues for research. A general overview of chordotonal organ ultrastructure is presented, followed by a summary of the current theories on mechanical coupling and transduction in monodynal, mononematic, Type 1 scolopidia, which characteristically innervate insect ears. Auditory organs of different insect taxa are reviewed, focusing primarily on tympanal organs, and with some consideration to Johnston's and subgenual organs. It is widely accepted that insect hearing organs evolved from pre-existing proprioceptive chordotonal organs. In addition to certain non-neural adaptations for hearing, such as tracheal expansion and cuticular thinning, the chordotonal organs themselves may have intrinsic specializations for sound reception and transduction, and these are discussed. In the future, an integrated approach, using traditional anatomical and physiological techniques in combination with new methodologies in immunohistochemistry, genetics, and biophysics, will assist in refining hypotheses on how chordotonal organs function, and, ultimately, lead to new insights into the peripheral mechanisms underlying hearing in insects. Copyright 2004 Wiley-Liss, Inc.