Functional organization of the tympanal organ of the flour moth, Ephestia kuehniella

Data about electrical recordings from the tympanic organ of the flour moth, Ephestia kuehniella, to acoustic stimuli is presented. The stimuli had a frequency that ranged from 5 to 100 kHz, with minimal intensities of 40 to 50 db (Odb = 0.0002 dynes/cm²) and maximal up to 110 db. The tympanic organ of E. kuehniella responded in the whole range of frequencies used and showed two sensitivity maxima, one at 20 kHz and the other at 60 kHz. It responded from 45 to 110 db. The electrical activity of the tympanic nerve consisted of a spontaneous discharge of a type B cell and a tonic discharge in response to acoustic stimulation, produced by four acoustic sense cells, called A₁, A₂, A₃, and A₄. All these acoustic sense cells respond in the whole frequency range used and they differ in the heights of their action potentials and in their sensitivity to acoustic stimuli. The possible biological significance of hearing in pyralid moths is discussed.     

Evolution of the metathoracic tympanal ear and its mesothoracic homologue in the Macrolepidoptera (Insecta)

Two independent methods of comparison, serial homology and phylogenetic character mapping, are employed to investigate the evolutionary origin of the noctuoid moth (Noctuoidea) ear sensory organ. First, neurobiotin and Janus green B staining techniques are used to describe a novel mesothoracic chordotonal organ in the hawkmoth, Manduca sexta, which is shown to be serially homologous to the noctuoid metathoracic tympanal organ. This chordotonal organ comprises a proximal scolopidial region with three bipolar sensory cells, and a long flexible strand (composed of attachment cells) that connects peripherally to an unspecialized membrane ventral to the axillary cord of the fore-wing. Homology to the tympanal chordotonal organ in the Noctuoidea is proposed from anatomical comparisons of the meso- and metathoracic nerve branches and their corresponding peripheral attachment sites. Second, the general structure (noting sensory cell numbers, gross anatomy, and location of peripheral attachment sites) of both meso- and metathoracic organs is surveyed in 23 species representing seven superfamilies of the Lepidoptera. The structure of the wing-hinge chordotonal organ in both thoracic segments was found to be remarkably conserved in all superfamilies of the Macrolepidoptera examined except the Noctuoidea, where fewer than three cells occur in the metathoracic ear (one cell in representatives of the Notodontidae and two cells in those of other families examined), and at the mesothoracic wing-hinge (two cells) in the Notodontidae only. By mapping cell numbers onto current phylogenies of the Macrolepidoptera, we demonstrate that the three-celled wing-hinge chordotonal organ, believed to be a wing proprioceptor, represents the plesiomorphic state from which the tympanal organ in the Noctuoidea evolved. This ’trend toward simplicity’ in the noctuoid ear contrasts an apparent ’trend toward complexity’ in several other insect hearing organs where atympanate homologues have been studied. The advantages to having fewer rather than more cells in the moth ear, which functions primarily to detect the echolocation calls of bats, is discussed. Accepted: 18 June 1999     

The accessory gland and metathoracic scent gland function in Oncopeltus fasciatus

The paper provides further clues as to the physiological function and biological significance of the ‘accessory gland’ in the metathoracic scent apparatus of the lygaeid Oncopeltus fasciatus. From various lines of evidence (gas chromatographic, cytochemical) it is concluded as probable that the accessory gland secretes small quantities of a mucopolysaccharide secretory product together with water. The difficulty of reconciling these data with other data indicating that the accessory gland is involved in the biosynthesis of the scent aldehydes is discussed. It is suggested that the water secreted into the median scent reservoir by the accessory gland provides O. fasciatus with a means of volumetric compensation for a diminished output of scent repellent.     

Range fractionation in the locust metathoracic femoral chordotonal organ

Summary Insect femoral chordotonal organs are internal proprioceptors which monitor the position and movements of the femur-tibia joint of the leg. The locust (Locusta migratoria) metathoracic femoral chordotonal organ is composed of approximately 100 neurones with a variety of response properties. In this study intracellular recordings were used to examine the range fractionation of phasic and tonic responses to tibial movements. Some neurones responded across the full range of leg angles, while others had restricted response ranges, and could therefore act as labeled lines. Neurones with maximal firing at mid-angles are described for the first time in a locust femoral chordotonal organ. Responses are discussed in terms of underlying structural constraints on signal transduction.Abbreviation (mt) FCO (metathoracic) femoral chordotonal organ     

The tympanal hearing organ of the parasitoid fly Ormia ochracea (Diptera, Tachinidae, Ormiini)

Tympanate hearing has evolved in at least 6 different orders of insects, but had not been reported until recently in the Diptera. This study presents a newly discovered tympanal hearing organ, in the parasitoid tachinid fly, Ormia ochracea. The hearing organ is described in terms of external and internal morphology, cellular organization of the sensory organ and preliminary neuroanatomy of the primary auditory afferents. The ear is located on the frontal face of the prothorax, directly behind the head capsule. Conspicuously visible are a pair of thin cuticular membranes specialized for audition, the prosternal tympanal membranes. Directly attached to these membranes, within the enlarged prosternal chamber, are a pair of auditory sensory organs, the bulbae acusticae. These sensory organs are unique among all auditory organs known so far because both are contained within an unpartitioned acoustic chamber. The prosternal chamber is connected to the outside by a pair of tracheae. The cellular anatomy of the fly's scolopophorous organ was investigated by light and electron microscopy. The bulba acustica is a typical chordotonal organ and it contains approximately 70 receptor cells. It is similar to other insect sensory organs associated with tympanal ears. The similarity of the cellular organization and tympanal morphology of the ormiine ear to the ears of other tympanate insects suggests that there are potent constraints in the design features of tympanal hearing organs, which must function to detect high frequency auditory signals over long distances. Each sensory organ is innervated by a branch of the frontal nerve of the fused thoracic ganglia. The primary auditory afferents project to each of the pro-, meso-, and metathoracic neuropils. The fly's hearing organ is sexually dimorphic, whereby the tympanal membranes are larger in females and the spiracles larger in males. The dimorphism presumably reflects differences in the acoustic behavior in the two sexes.     

In vitro effect of various mitogens on starfish (Asterias rubens) axial organ cells

The effects of various mitogens on axial organ (AO) cells of the sea star have been studied. Pokeweed mitogen (PWM) stimulates [³H]thymidine incorporation by the whole population of axial organ cells of the sea star. This effect occurs 24 hr after the addition of PWM and is maximal at 40 μg/ml. In contrast, no stimulation is observed when coelomocytes are treated with PWM under the same conditions. No stimulation of the whole AO cell population is observed in the presence of Con A or LPS. However, the AO cell population can be divided, on the basis of surface adherence properties, into two subpopulations, adherent and nonadherent. Con A stimulates the nonadherent cells, but not the adherent cells: The stimulating effect is maximal 24 hr after addition of Con A and at 0.2–0.5 μg/ml. In contrast, LPS stimulates the adherent but not the nonadherent cells and the stimulating effect is maximal at 24 hr and at 45 μg/ml.     

The tympanal hearing organ of a fly: phylogenetic analysis of its morphological origins

A key adaptation for any parasitoid insect is the sensory modality that it uses to locate its host insect. All members of the speciose family Tachinidae (Diptera) are parasitoids, but only flies of the tribe Orminini use acoustic cues to find their hosts. Ormiine flies are parasitoids of various genera of crickets and katydids. Gravid females of one ormiine species, Ormia ochracea, hear the reproductive calling song of male field crickets and home in on those calls to locate their hosts. While many flies possess various kinds of ears to detect airborne sounds, only ormiine flies have been reported to possess true tympanal hearing organs. Such organs are wellknown to occur in their cricket and katydid hosts. The ormiine ear is an evolutionary innovation within Diptera. Our objective was to trace the phylogenetic origins of the tympanal hearing organ among higher flies. Since the ormiine hearing organ is a complex organ within the prothorax, we examined possible precursor structures in the prothoraces of selected Diptera. We have uncovered a suite of characters that define the ormiine ear. These characters in the prothorax include a pair of prosternal tympanal membranes, a pair of chordotonal sensory organs, and modifications of the tracheal system. We have been able to identify and trace the presumptive homologs of these ormiine characters through selected species of related Diptera, using the method of outgroup comparison.Dedicated to the memory of Dr. Edmund A. ArbasThis work was supported by grants from NIH (5RO1 DC 00103), NIMH (IKOS MH01148-01), NSF (240-1879A) and Hatch (NYC-191403) to R.R.H. and the Swiss Science Foundation and the Janggen-Pöhn Foundation to D.R.     

Responses and locations of neurones in the locust metathoracic femoral chordotonal organ

Summary Insect legs possess chordotonal organs which monitor leg angle, and the direction, velocity and acceleration of leg movements. The locust metathoracic femoral chordotonal organ (mtFCO) has previously been studied morphologically and physiologically, but no detailed analysis of the responses of individual neurones, and their location in the organ has so far been produced. By recording from, and staining mtFCO neurones I have been able to compile for the first time such a map. The distribution of neurone somata in the locust mtFCO is more complex than previously thought: receptors sensitive to both stretch and relaxation of the apodeme are distributed throughout the organ. Seventeen response types were encountered. Neurones with a particular response type have somata in comparable locations within the mtFCO. Comparisons are made between the response types found in the stick insect and those in the locust. The possible functions of some of the responses are discussed.Abbreviation (mt)FCO (metathoracic) femoral chordotonal organ - F-T femur-tibia     

The tympanal hearing organ of the parasitoid fly Ormia ochracea (Diptera,Tachinidae, Ormiini)

Tympanate hearing has evolved in at least 6 different orders of insects, but had not been reported until recently in the Diptera. This study presents a newly discovered tympanal hearing organ, in the parasitoid tachinid fly, Ormia ochracea. The hearing organ is described in terms of external and internal morphology, cellular organization of the sensory organ and preliminary neuroanatomy of the primary auditory afferents. The ear is located on the frontal face of the prothorax, directly behind the head capsule. Conspicuously visible are a pair of thin cuticular membranes specialized for audition, the prosternal tympanal membranes. Directly attached to these membranes, within the enlarged prosternal chamber, are a pair of auditory sensory organs, the bulbae acusticae. These sensory organs are unique among all auditory organs known so far because both are contained within an unpartitioned acoustic chamber. The prosternal chamber is connected to the outside by a pair of tracheae. The cellular anatomy of the fly's scolopophorous organ was investigated by light and electron microscopy. The bulba acustica is a typical chordotonal organ and it contains approximately 70 receptor cells. It is similar to other insect sensory organs associated with tympanal ears.The similarity of the cellular organization and tympanal morphology of the ormiine ear to the ears of other tympanate insects suggests that there are potent constraints in the design features of tympanal hearing organs, which must function to detect high frequency auditory signals over long distances. Each sensory organ is innervated by a branch of the frontal nerve of the fused thoracic ganglia. The primary auditory afferents project to each of the pro-, meso-, and metathoracic neuropils. The fly's hearing organ is sexually dimorphic, whereby the tympanal membranes are larger in females and the spiracles larger in males. The dimorphism presumably reflects differences in the acoustic behavior in the two sexes.     

Structure of the green lacewing tympanal organ (Chrysopa carnea,neuroptera)

Small swellings near the base of the radial vein in each fore wing of the green lacewing, Chrysopa carnea, resemble typical insect tympanal organs, but some important differences are apparent. The swellings are bounded dorsally and laterally by thick cuticle and ventrally by thin, membranous cuticle. The ventral membrane is formed by a single, thin sheet of exocuticle with flattened hypodermis internally, but lacks the tracheal component that forms part of the tympanum in the typical insect tympanal organ. The portion of the membrane beneath each swelling is rippled while proximally it is smooth. In contrast to typical insect tympanal organs, the swellings in C. carnea are largely fluid-filled since an unexpanded trachea runs through each organ. A distal and a proximal chordotonal organ composed of typical chordotonal sensory units are associated with each swelling. The distal organ contains from five to seven units while the proximal organ is composed of from 18 to 20 units. Each sensory unit is composed of three readily identifiable cells. Distally, an attachment cell unites with the membrane and is contiguous with the scolopale cell, which surrounds the dendrite of the bipolar neuron. On the basis of the morphological evidence, one would not expect these swellings to function as sound receptors. However, the results of physiological and behavioral experiments, presented elsewhere, show that these organs are receptors for ultrasound.     

Development of the tympanal organ in larvae of the migratory locust (Locusta migratoria)

Summary The tympanal organ of the migratory locust acquires its definitive form during larval development. All the receptor cells (90–100) are present in the 1st instar, whereas the differentiation of the tympanum and the cuticular structures it bears proceeds in steps from one instar to the next. The elevated process is the earliest such structure to appear (2nd instar); it is followed by the pyriform vesicle (3rd instar) and folded body (4th instar). The styliform body first appears in the imago. Although the typical arrangement of the receptor cells is already discernible in the 1st instar, some of the attachment sites change during development, the final configuration appearing only in the imago.Supported by the Deutsche Forschungsgemeinschaft (Ka 498/2)     

Mechanics of the transduction of sound in the tympanal organ of adults and larvae of locusts

Summary The mechanical transmission of sound in the tympanal organ of adults and 5th instar larvae ofLocusta migratoria andSchistocerca gregaria has been investigated by means of stroboscopic measurements within a frequency range from 1–20 kHz.Frequency dependent spatial distributions of amplitudes and phases of oscillation on the tympanal membrane and the Müller's organ could be demonstrated. Cuticular structures on the membrane may act as a lever arm (e.g. elevated process) and cause a transformation of the (unidimensional) membrane motion into components of displacements in the Müller's organ perpendicular, as well as even parallel, to the membrane.Sites of maximum relative displacements at distinct frequencies are found to be correlated to the course of the dendrites of the acoustic receptor cells. Differences in morphology of the tympanal organ between the two species as well as between adults and larvae always correspond to differences in the mechanical properties (resonances etc.). Consequently, differences or changes in the neurophysiological response characteristics of the different receptor cells have been found.Based upon these findings a correlation between the anatomical and physiological classification of the receptor cell groups is presented.Abbreviations T1, T2, T3, T6, T7 reference points on the tympanal membrane - M1, M4 reference points on the ganglion of the Müller's organ - K1, K2 reference points on the elevated process     

The effect of the microsporidan, Nosema algerae, on Anopheles stephensi

A bioassay method was established to examine infectivity differences between different batches of Nosema algerae spores. The IC₅₀ of N. algerae spores produced in one unusual host, Heliothis zea, was the same as for spores from the normal mosquito host, Anopheles stephensi. Soil and sand bottoms caused an approximate 200–400 fold increase in the IC₅₀. Nosematosis had little effect on the survival of larvae and pupae but the adult life span was reduced to the extent that malaria transmission would be doubtful.     

The taxonomic position of Sphaerocarpos and Riella as indicated by their flavonoid chemistry

The major flavonoid glycosides of Sphaerocarpos texanus are luteolin 7-O-glucuronide and 7,4′-di-O-glucuronide. Riella americana and R. affinis both contain apigenin, chrysoeriol and luteolin 7-O-glucuronides but R. americana additionally contains luteolin 3′-O-glucuronide. This finding supports the inclusion of Sphaerocarpaceae and Riellaceae in the order Marchantiales rather than their separation into another order.     

Morphology of the central projections of physiologically characterised neurones from the locust metathoracic femoral chordotonal organ

Summary The metathoracic femoral chordotonal organ of the locust (Locusta migratoria) is an internal proprioceptor composed of mechanosensory neurones which respond to tibial position, velocity, or acceleration, or to combinations of these parameters. Discriminant function analyses confirmed the visual observation that neurones with different responses to tibial movements had different central branching patterns. Some aspects of the projections were consistent for all neurones (e.g., the path taken by the main neurite through the metathoracic ganglion), whereas other regions of branches were consistently reduced or missing in some response classes. Some position-and-acceleration receptors had no main branches off the main neurite, and must therefore make relatively restricted contact with motor neurones and interneurones. Phasic or tonic neurones which responded in ranges of tibial extension had branches which projected further medial in Dorsal Commissures III and IV than similar neurones which responded in ranges of tibial flexion. I compare my results to previous studies of mapping in the insect CNS.Abbreviations (ms) (mt)FCO (mesothoracic) (metathoracic) femoral chordotonal organ - ANOVA Analysis of Variance     

Ultrastructure of the Z organ in Xiphinema ifacolum

Bieve-Zacheo T., Zacheo G. and Lamberti F. 1985. Ultrastructure of the Z organ in Xiphinema ifacolum. International Journal for Parasitology15: 453–461. The uterus in Xiphinema ifacolum can be divided into uterus proper, a 77 μm long tube and a lemon-shaped Z organ, about 28 μm long and 18 μm wide, placed between the oviduct and the uterus proper. The Z organ consists of a thick outer muscular layer of 120 cells, arranged in 20 rings of six cells each and a thin inner epithelium layer, lining the lumen. The epithelial cell walls, lining the lumen of the Z organ are thicker than those lining the uterus proper and are strongly folded. The crests of some of these folds carry six large apophyses, all about the same size and shape, these occupy the full length of the organ, becoming thicker towards the center of the lumen. There are many tubules near the surfaces of the apophyses, the contents of which can be dissolved by treatment with pepsin and pronase, indicating that they are proteins. This material probably consists of secretions which are squeezed out of the apophyses by a passing egg and may function in the formation or hardening of the egg shell.