Central nervous projections of mechanoreceptors in the spider Cupiennius salei Keys.

Summary The basic organization of sensory projections in the suboesophageal central nervous system of a spider (Cupiennius salei Keys.) was analyzed with anterograde cobalt fills and a modified Golgi rapid method. The projections of three lyriform slit sense organs and of tactile hairs located proximally on the legs are described and related to central nerve tracts. There are five main longitudinal sensory tracts in the central region of the suboesophageal nervous mass arranged one above the other. Whereas the three dorsal ones contain fibers from the lyriform organs, the two ventral ones contain axons from the hair receptors. Axons from all three lyriform organs have typical shapes and widely arborizing ipsilateral intersegmental branches and a few contralateral ones. The terminal branches of the afferent projections from identical lyriform organs on each leg form characteristic longitudinal pathways, typical of each organ: U-shaped, O-shaped, or two parallel bundles. The terminations of the hair sensilla are ipsilateral and intersegmental. Two large bilaterally arranged longitudinal sensory association tracts receive inputs from all legs including the dense arborizations from tactile hairs, lyriform organs, and other sense organs. These tracts may serve as important integrating neuropils of the suboesophageal central nervous system.     

External structure of the sensillum capitulum,a hygro- and thermoreceptive sensillum of the cockroach,Periplaneta americana

Summary The antennal hygro- and thermoreceptive sensillum (sensillum capitulum) of the cockraoch, Periplaneta americana, has been identified electrophysiologically and examined by scanning electron microscopy. It appears basiconic and has a characteristic cuticular apparatus; a mushroom-shaped inner stem and a non-perforated outer wall. The head of the inner stem, which is a cap of about 0.5 m diameter, protrudes from the distal margin of the outer wall. The inner stem is not perforated, though in some cases a tiny hollow is observed in the apex of the cap. This kind of cuticular apparatus is not found in other sensilla and may be modality-specific to hygro- and/or thermoreception. The sensillum capitulum occurs singly on the distal part of each alternating segment of the flagellum and on each segment of some distal meristal segments.Supported by Grant-in-Aid for Special Project Research Mechanism of animal behavior from the Ministry of Education (Japan)     

Sexual dimorphism of tarsal receptors and sensory equipment of the ovipositor in the European corn borer,Ostrinia nubilalis

Summary Sensilla on legs and ovipositor of the moth Ostrinia nubilalis were investigated by light and scanning electron microscopy. The ovipositor is composed of two papillae densely packed with medium length mechanoreceptor sensilla (MRb: 80–160 m, n=420–460). Long mechanoreceptor sensilla (MRa: 250–300 m, n=20–24) and contact chemoreceptors (CRa: 30–40 m, n=20–28) are evenly distributed at the periphery of these papillae. Legs support contact chemoreceptors (CRa), scattered among the scales. The pretarsus structure of each leg includes a single contact chemoreceptor (125 m) inserted dorsally. The fifth tarsomere bears a ventral area without scales on which contact chemoreceptors are disposed in two parallel rows (CRb: 40–60 m). A sexual dimorphism was found in the number and density of these sensilla (females: mean = 5.3, SD=1.0; males: mean = 3.3, SD=0.7), and in the size of the sensory field. The possible involvement of these sensory structures in oviposition site selection is discussed.     

Ultrastructure of Haller's organ in the tick Amblyomma americanum (L.)

Summary Haller's organ on the tarsus of the tick Amblyomma americanum (L.) (Acarina: Ixodidae; nymphal stage) was studied by scanning and transmission electron microscopy. It consists of a distal bristle group, (the anterior pit), and a proximal capsule which encloses several sensilla. The seven sensilla of the anterior pit (A1–A7) are all thick-walled and multi-innervated (2–9 neurons), but at least three different types can be differentiated. Sensilla A1 and A2 possess large, plugged pores (>1000 Å) and are the only sensilla with branching dendrites. A3 and A5 are characterized by a spoke-wheel arrangement of the cuticle wall and very fine pores (100–200 Å) penetrating the spokes centrally; A4, A6, and A7 do not exhibit any pore system but a single opening at the bristle tip is assumed.The capsule contains seven thin-walled, blunt-tipped sensilla, and several non-sensory cuticular projections (pleomorphs). All of these sensilla possess large plugged pores in the cuticle wall and numerous dendritic branches of several neurons (3–5) in the lumen. Glandular openings were found inside the capsule; their significance is discussed.The fine structure of Haller's organ supports the functions postulated by Lees (1948), namely olfaction for the capsule and humidity reception (among others) for the anterior pit.This research was supported in part by the Office of Naval Research, and by NIH Training grant ES 00069. Paper no. 3459 of the Journal Series of the North Carolina State University Agricultural Experiment Station, Raleigh.     

Central projections of campaniform sensilla on the cerci of crickets and cockroaches

Summary Campaniform sensilla associated with filiform hairs comprise an important receptor type of the multimodal sensory system of the cerci of crickets and cockroaches. Their axon projections were investigated using iontophoretic cobalt injection into single sensilla.In crickets (Gryllus bimaculatus, Acheta domestica), six different types of cereal campaniform sensilla projections can be distinguished on the basis of their axonal arborizations and terminations. Typically, a proportion of cereal campaniform sensilla, associated with long filiform hairs, give rise to axons that ascend as through fibres from the terminal ganglion to reach the sixth abdominal ganglion. Cereal campaniform sensilla associated with clavate hairs have projections restricted to the terminal ganglion alone.Whereas in crickets axons of cercal campaniform sensilla invade only certain segmental neuropils in the terminal ganglion, in cockroaches (Periplaneta americana) axons from cercal campaniform sensilla branch in every segmental neuropil. A proportion of cereal campaniform sensilla in this species also gives rise to through fibres to the fifth abdominal ganglion.We discuss morphological and functional interpretations of differences between crickets and cockroaches and consider the significance of this type of receptor in the context of previous studies of the cercal system.     

The hair-peg organs of the shore crab,Carcinus maenas (Crustacea,Decapoda): Ultrastructure and functional properties of sensilla sensitive to changes in seawater concentration

Summary The hair-peg organs of the shore crab, Carcinus maenas, are modified hair-sensilla. A small hair shaft (peg) is surrounded by a tuft of solid cuticular bristles (hairs). Each hair-peg organ is innervated by 6 sensory neurons, 2 of which have scolopidial (type-I) dendrites. The outer segments of all dendrites pass through a cuticular canal extending to the articulated hair base in which the 2 type-I dendrites terminate. The other 4 (type-II) dendrites reach the clavate tip of the hair shaft and have access to a terminal pore and a large sickle-shaped aperture. Three inner and 8–12 outer enveloping cells belong to a hair-peg organ. The innermost enveloping cell contains a scolopale, which has desmosomal connections to the ciliary rootlets of the type-I dendrites. An inner and an outer sensillum lymph space are present. The ultrastructural features of the dendrites and the cuticular apparatus indicate that the hair-peg organs are bimodal sensilla, comprising 2 mechano- and 4 chemosensitive sensory neurons. Extracellular recordings from the leg nerve indicate that the chemosensitive neurons of the hair-peg organs respond to changes in seawater concentration in the physiological range of Carcinus maenas.Supported by the Deutsche Forschungsgemeinschaft (SFB 45/A1; W. Gnatzy)     

Morphologie,Larvalentwicklung und Haarsensillen des Tastbeinpaares der Gei\elspinneHeterophrynus longicornis Butler (Arach., Amblypygi)

Zusammenfassung Die Gei\elspinneHeterophrynus longicornis orientiert sich überwiegend mit Hilfe von cuticularen Haarsensillen. Borstenhaare und Trichobothrien treten besonders an den Beinen auf. Das zu einem Tastbein umgeformte, vielfach gegliederte 1. Beinpaar trÄgt au\erdem 5 weitere Typen von Haarsensillen- und 3 anders gestaltete cuticulare Sinnesorgane.Die Haarsensillen der verschiedenen Entwicklungsstadien der Gei\elspinne wurden licht und rasterelektronenmikroskopisch untersucht und ausgezÄhlt. Anschlie\ende elektronenmikroskopische Untersuchungen erlauben die Zuordnung folgender physiologischer Funktionen: Borstenhaare — Kontaktchemo- und Mechanorezeptoren; Trichobothrien — Mechanorezeptoren (Ferntastsinnesorgane); Porenhaare (2 Typen) — olfaktorische Chemorezeptoren; Kölbchenhaare — Chemorezeptoren i.w.S. (auch hygrosensitiv?); StÄbchenhaare (2 Typen) — Chemorezeptoren i.w.S. Die umgeformten Krallen sowie das Gruben- und das Plattenorgan sind vermutlich ebenfalls Chemorezeptoren i.w.S. (auch hygro-thermosensitiv?).Aus der Anzahl der Sensillen des Tastbeintarsus ergibt sich eine theoretische Axonzahl von 2250 an der Spitze bzw. 21 500 an der Basis. AuszÄhlungen von EM-Schnittbildern stimmen damit gut überein. Alle Fasern ( um 0,2 m) sind wahrscheinlich afferent und ziehen getrennt zum ZNS. Daneben finden sich in jedem Tarsalnerv eine oder mehrere Riesenfasern ( 10–20m), auf die kleinere Axone bereits vom Glied 1 an aufgeschaltet werden. Wahrscheinlich handelt es sich hier um ein Schnelleitsystem, das periphere Reize möglichst rasch zum ZNS bringt.Ein Vergleich mit Untersuchungen an anderen Arten macht wahrscheinlich, da\ die Ausstattung mit Sinnesorganen innerhalb der Ordnung Amblypygi sehr Ähnlich ist und damit der Ähnlichen Lebensweise der Arten entspricht.

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Morphology, larval development, and hair sensilla of the antenniform legs of the whip spiderHeterophrynus longicornis Butler (Arach., Amblypygi)

Summary The whip spiderHeterophrynus longicornis uses cuticular hair sensilla for orientation. Bristles and trichobothria occur mainly on the walking legs. The first pair of legs, which are modified appendages, bear five additional types of sensilla as well as three other sensory structures.The hair sensilla of different developmental stages were studied by light- and scanning electron microscopy for quantitative evaluations. Transmission electron microscopy permitted to attribute the following tentative functions to certain sensilla: bristles — contact chemoreception and mechanoreception; trichobothria — mechanoreception (touch-at-a-distance); porous sensilla (2 types)— olfaction; club sensilla — chemoreception (hygroreception?); rod sensilla — chemoreceptors. The modified claws, the pit organ and the plate organ are supposedly also chemoreceptors (eventually humidity and/or thermoreceptors).Based on the number of sensilla on the tarsus of a first leg we calculated a theoretical number of 2250 axons for the first tarsal segment and 21 500 axons for the level of the last tarsal segment. Actual counts done on EM-pictures yielded very similar numbers. This means that practically all nerve fibres (0.2/gmm diameter) are afferent and that all of them proceed toward the CNS. Furthermore, each tarsal nerve contains one or several giant fibres (10–20m diameter) which receive synapses from small axons already in the distalmost segment 1. We interpret this findings as a fast conduction pathway to relate peripheral stimuli quickly to the CNS.A comparison with the few studies on other Amblypygi renders it likely that their sensory equipment is rather similar, which corresponds to their similar life habits.

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Mit Unterstützung der Deutschen Forschungsgemeinschaft     

Morphogenesis of mechanoreceptor and epidermal cells of crickets during the last instar,and its relation to molting-hormone level

Summary (1) The fine structure of the cercal campaniform sensilla and epidermal cells of Gryllus bimaculatus Deg. (Saltatoria, Gryllidae) was examined, and the ecdysteroid level was monitored throughout the last larval instar. (2) The epidermal cells show changes in shape, cytoplasmic inclusions and differentiation of the apical cell membrane, coupled to the phases of buildup and breakdown of the (cercus) cuticle. (3) The imaginal epicuticle of the epidermal cells begins to form later (by about approximately 6 h) than that of the campaniform sensilla. (4) The campaniform sensilla were studied with respect to (a) the morphogenesis of the cuticular apparatus, (b) the inclusion of phenol oxidases in the cuticular apparatus, and (c) changes in the sensory apparatus preparatory to molting. (5) After apolysis the folding of the tormogen-cell wall into microvilli transiently disappears. Microvilli re-form shortly before imaginai ecdysis, and at the same time an outer receptor-lymph space develops. The role of the tormogen-cell plaques is discussed. (6) The levels of - and -ecdysone were determined separately by radioimmunoassay. (7) At the beginning of the instar the hormone level, especially that of -ecdysone, falls. Prior to apolysis, the concentration of -ecdysone rises, reaching an intermediate peak after apolysis is complete. The maximum hormone concentration (approximately 2,000 ng/g) is reached after the cuticulin layer is deposited, primarily due to the increase in -ecdysone. While the proecdysial cuticle is forming, the hormone titer is reduced; at this time -ecdysone is its chief component. (8) The identification of the ecdysteroids monitored by radioimmunoassay was confirmed by gas chromatography.This paper is dedicated to Professor H. Risler on the occasion of his 65th birthdaySupported by the Deutsche Forschungsgemeinschaft     

Alpha-factor leader sequence-directed transport of Escherichia coli beta-galactosidase in the secretory pathway of Saccharomyces cerevisiae

Summary The constuction of two fused genes is described. One involves the in-frame fusion of the yeast prepro--factor coding sequence, and the Escherichia coli lac Z gene. The second gene fusion utilizes a 103 bp yeast invertase NH₂-terminal coding sequence at the fusion junction of the hybrid gene described above. The gene fusions, under the control of the -factor promoter, expressed active -galactosidase in haploid yeast cells. The activity could be regulated in a temperature-sensitive sir3 mutant. The incorporation of the invertase coding sequence at the MF1-lacZ fusion junction provided significantly higher levels of -galactosidase activity. A substantial quantity of the hybrid proteins generated from the gene fusions was primarily localized in the intracellular membranes of yeast cells, while a processed form could be secreted into the periplasm.A portion of this work appeared in Biotechnology Progress (Das and Shultz 1986) as proceedings of the symposium on Industrial Scale Protein Purification, held at the annual meeting of the Institute of Chemical Engineers in Miami Beach, Fla, USA on November 4, 1986     

Specific Cd2+ uptake of encapsulated Aureobasidium pullulans biosorbents

Calcium alginate capsules containing Aureobasidium pullulans cells were prepared by an in-situ one-step method. The Cd²⁺uptakes of free biosorbent and capsule biosorbent were described well by the Freundlich isotherms. The Cd²⁺ uptake of capsule biosorbent was lower than that of free biosorbent with Cd^{2 +}at 100 mg l^–1. The total cadmium uptake of capsule biosorbent increased with the increase in encapsulated cell density and plateaued at a value of 23 g Cd²⁺/capsule with 150 g dry biosorbent l^–1 core volume of a capsule. The specific cadmium uptake of encapsulated biosorbent was 85% to that of free biosorbent at 35 g biosorbent dry weight l^–1 core volume of a capsule, decreased to 35% at 176 g biosorbent dry weight l^–1.     

Ecto-ATPase/phosphatase activity in the olfactory sensilla of the spiny lobster,Panulirus argus: localization and characterization

Summary Electrophysiological studies have shown that the olfactory organ (antennule) of the spiny lobster, Panulirus argus, has chemoreceptors that are selectively excited by adenine nucleotides in seawater. Biochemical studies have revealed that these same nucleotides can be rapidly dephosphorylated by ectoenzymes associated with the olfactory sensilla (aesthetascs). In this study the distribution of ecto-ATPase/phosphatase activity within aesthetascs was determined cytochemically and the nature of the adenine-nucleotide dephosphorylating activity was dissected biochemically. Cytochemically, the distribution of ATP-dephosphorylating activity was similar to that shown previously for AMP and -glycerol phosphate; i.e., cerium phosphate reaction product was specifically localized to the transitional zone where the sensory dendrites develop cilia and branch to form the outer dendritic segments. Unlike the dephosphorylation of AMP and -glycerol phosphate, Mg²⁺ or Ca²⁺ was required for ecto-ATPase/phosphatase activity. Biochemical measures of both AMP-and ATP-dephosphorylating activity within aesthetascs corroborated the cytochemical evidence that these activities are localized to the transitional zone. A major portion of the AMP dephosphorylation (about 67%) derives from nonspecific alkaline phosphatase activity that is insensitive to levamisole and L-bromotetramisole. In contrast, nonspecific phosphatase activity accounted for a much smaller part of the ATP dephosphorylation (about 15%). Ectoenzymatic activity in the transitional zone may be an important means of removing excitatory/inhibitory nucleotides from this region.Abbreviations ADP Adenosine 5-diphosphate - AMP adenosine 5-monophosphate - AMPCP , -methylene ADP - ASW artificial seawater - ATP adenosine 5-triphosphate - -GP -glycerol phosphate - EM electron microscopy     

Ultrastructure of the osphradium of Aplysia californica

Summary The osphradium of Aplysia californica, a sensory organ, is a small yellow-brown epithelial patch located in the mantle cavity immediately anterior to the rostral attachment of the gill. Scanning electron microscopy reveals a round ellipsoid structure of 0.6–1 mm in diameter with a central, occasionally folded, sensory epithelium. The central area is covered with microvilli and surrounded by a densely ciliated epithelium. Transmission electron micrographs show that the columnar supporting cells in the sensory epithelium contain an abundance of apical pigment granules and microvilli. Between the epithelial-supporting cells, the putative sensory elements consist of thin neurites (0.4–1.5 m in diameter) that reach the sea-water side of the osphradium. The neurites contain many neurotubules, mitochondria, vesicles and cilia in their apices. The nerve endings originate from cell bodies up to 40 m below the epithelium or in the osphradial ganglion itself, as revealed by electron microscopy and retrograde labeling with Lucifer yellow. There appear to be two populations of putative sensory cells, a large population of heavily stained cell bodies 4–10 m in diameter and a few scattered cells of large diameter (25–60 m). Following lanthanum impregnation, septate junctions can be seen between all types of cells in the epithelium, 3–5 m below the sea-water surface. This study provides new information for further investigation of osmo- and mechanosensation in Aplysia californica.     

Proprioceptors and sensory nerves in the legs of a spider,Cupiennius salei (Arachnida,Araneida)

Summary Retrograde CoS-impregnation was used to trace and map the course of sensory nerves and the distribution and innervation of the various proprioceptor types in all leg segments of Cupiennius salei, a Ctenid spider.1. Sensory nerve branches. In both the tibia and femur, axons of all proprioceptor types ascend in just two lateral nerves which do not merge with the main leg nerve until they reach the next proximal joint region. In the short segments — coxa, trochanter, patella, and tarsus — axons of the internal joint receptors often run separately from those of the other sensilla. Axons of the large lyriform slit sense organ at the dorsal metatarsus and of the trichobothria join with only a few hair axons and form their own nerve branches (Figs. 1, 2, 3).2. Proprioceptors. Each of the seven leg joints is supplied with at least one set of the well-known internal joint receptors, slit sensilla (single slits and lyriform organs), and long cuticular hairs. In addition, we found previously unnoticed hair plates on both sides of the coxa, near the prosoma/coxa joint; they are deflected by the articular membrane during joint movements (Fig. 4).3. Sensory cells and innervation. CoS-impregnation shows that each slit of the slit sense organs — be it a single slit or several slits in a lyriform organ — is innervated by two bipolar sensory cells (Fig. 6). We also confirm previous reports of multiple innervation in the internal joint receptors and in the long joint hairs and cuticular spines.Most of the ascending nerve branches run just beneath the cuticle for at least a short distance (Fig. 5); hence they are convenient sites for electrophysiological recordings of sensory activity even in freely walking spiders.     

Observations on the fine structure of the cercaria of Notocotylus attenuatus and formation of the cyst wall of the metacercaria

Summary The dorsal tegument of the mature cercaria of Notocotylus attenuatus is a syncytial, cytoplasmic layer, containing two types of secretory granule which are identifiable ultrastructurally. The type 1 secretory bodies are electron lucid, whereas most type 2 granules have a banded appearance. The ventral tegument contains granules which are secreted from the type 3 cells; the type 3 granules are membrane bound, electron dense, and consist of both an amorphous and a finely striated zone. The type 4 cells mainly contain cigar-shaped granules consisting of an amorphous core surrounded by concentric striations. The granules exhibit structural variability in shape and content. The type 4 cells undergo a cellular migration to the tegument during encystment. The structure of the posterior-lateral glands and mode of secretion of the granules are described. Possible functions of microtubules are discussed for each cell type. Details of some secretory processes involved in the formation of the hemispherical cyst wall are described. The layers of the cyst wall may be related to the granular contents of the various parenchymal cells of the cercaria. The tegument of the metacercaria originates primarily from the cytoplasm of the type 1, type 2, type 3 and type 4 cells.     

Meiotic studies ofElymus nutans andE. jacquemontii (Poaceae,Triticeae) and their hybrids withPseudoroegneria spicata and seventeenElymus species

Hybridizations ofElymus nutans andE. jacquemontii were carried out with one species ofPseudoroegneria (S genome), and 20Elymus species, each containing either of the SH, SY, SYH, or SYW genomes. Chromosome configurations were analysed at metaphase I of the two target taxa and their interspecific hybrids. It is concluded that (i)E. nutans is an allohexaploid containing the SYH genomes, andE. jacquemontii is an allotetraploid having the SY genomes; (ii) the genomic affinity is associated with the geographic distance between the species studied; (iii) minor genomic structural rearrangements have occurred within the hexaploid taxon ofE. nutans.     

Electroantennogram responses of the Mediterranean fruit fly, Ceratitis capitata, to the volatile constituents of nectarines

Electroantennograms (EAGs) were recorded from laboratory-reared, male and female Ceratitis capitata (medfly) in response to individual volatiles identified from ripe nectarines. Uniformity in EAG response between the sexes was observed for most test compounds. Only 10 volatiles, of the 44 nectarine volatiles tested, elicited significantly different EAG responses between the sexes. No correlation was observed between the magnitude of antennal responsiveness and the concentration of a particular volatile in the headspace odor of ripe nectarines. The most abundant (major) nectarine volatiles were among the least EAG stimulatory compounds tested. And certain minor and trace volatiles were the most potent compounds in eliciting EAGs. Moreover, the magnitude of antennal response to a nectarine volatile was related to the functional-group, chain-length, and unsaturation of the compound. The degree of potency of the compounds was as follows: six-carbon unsaturated aldehydes and alcoholsmethyl and ethyl hexanoates and octanoateshexenyl acetates and monoterpenes>shorter chain-length acetates and alcohols>lactones. Unsaturated aldehydes, alcohols, and acetates generally elicited larger EAGs than their saturated analogs, with the (E)-2-isomers being the most potent isomeric configurations. In addition, medfly antennae exhibited long recovery periods (i.e., >10 sec.) for the EAG tracings to return to baseline potential after stimulations with certain classes of compounds, e.g., C₆ to C₈ acid esters, monoterpenes, and hexen-1-ols. The potential adaptiveness to medflies for selective sensitivity to these volatiles is discussed.     

Sensory control of leg movement in the stick insect Carausius morosus

Hind legs with crossed receptor-apodemes of the femoral chordotonal organ when making a step during walking often do not release the ground after reaching the extreme posterior position. After putting a clamp on the trochanter (stimulation of the campaniform sensilla) the leg is no longer protracted during walking. However, during searching-movements the same leg is moved very far forwards. The anatomical situation of the campaniform sensilla on the trochanter and the sensory innervation of the trochanter is described. After removal of the hair-rows and continuously stimulating the hair-plate at the thorax-coxa-joint the extreme anterior and posterior positions of the leg in walking are displaced in the posterior direction. Front and middle legs operated in this way sometimes do not release the ground at the end of retraction. In searching-movements the same leg is moved in a normal way. If only one side of a decerebrated animal goes over a step, then on the other side a compensatory effect is observed. The main source of this compensatory information appears to be the BF1-hair-plates. If the animal has to drag a weight the extreme anterior and posterior positions of the middle and hind legs are displaced in the anterior direction. Crossing the receptor-apodeme of the femoral chordotonal organ, when it causes the leg to remain in the protraction phase, displaces the extreme posterior position of the ipsilateral leg in front of the operated one in the posterior direction. Influences of different sources on the extreme posterior position can superimpose. A model is presented which combines both a central programme and peripheral sensory influence. The word programme used here means that it does not only determine the motor output but also determines the reactions to particular afferences. The fact that the reaction to a stimulus depends on the internal state of the CNS is also represented by the model.Supported by Deutsche Forschungsgemeinschaft     

Light- and electron-microscopic analysis of a complex sensory organ: The tegula of Locusta migratoria

Summary Structure and organization of the tegula, a cupola-shaped structure located at the anterior base of the wings of locusts, is described using various morphological methods. Based on histological and cytological criteria, two different sensory systems are distinguished: (1) a field of mechanoreceptive hairs, and (2) a chordotonal organ. The total number of sensory cells corresponds to the number of axons within the nerve supporting the tegula. The hairs are situated at the posterior region of the tegula, and each hair is innervated by only one sensory cell. The complex architecture of the chordotonal organ is analyzed and the attachment of the scolopidia to the cuticle is described. A single scolopidium makes contact with several epidermal cells. The attachment cells run in parallel and are oriented longitudinally within the tegula, being connected to each other and to the epidermal cells by desmosomes. A function in relation to wing movements during flight is suggested for the two sensory systems within the mixed sense organ, tegula.     

Ultrastructure and behaviour of the spindle pole body of the aphid-pathogenic fungusErynia neoaphidis

Summary A detailed account of the ultrastructure and behaviour of the spindle pole body (SPB) of the entomophthoraceous fungusErynia neoaphidis is presented for the first time.The SPB consists of extranuclear (ENC) and intranuclear (INC) components. The ENC is a saucepan-shaped structure which lies in a pocket of the nuclear envelope. It is composed of a forked, fibrillar handle and a shallow, cylindrical pan. The pan has a wall of two layers, both of which are thickened with a regular periodicity so that they appear to be beaded. It is postulated that the pan is formed from rough endoplasmic reticulum and that it synthesizes the amorphous, electron-dense material coating the ENC.The INC is a saucer-shaped, electron-dense plaque in which the ends of the spindle microtubules terminate. During metaphase, a clear zone separates the INC from the nuclear envelope and persists until telophase. The roles of the amorphous, electron-dense material and the clear zone as well as the method of SPB replication are discussed.     

Long,smooth hair sensilla on the spider leg coxa: Sensory physiology,central projection pattern,and proprioceptive function (Arachnida,Araneida)

Summary Rows of long, smooth hair sensilla situated on both sides of the leg coxae were examined in the spider Cupiennius salei (Ctenidae). The hair shafts point into the space between adjacent legs and are deflected when the hairs of one coxa touch the cuticle of the neighboring coxa. 1. Unlike the serrated hair shafts of the ubiquitous tactile and chemosensitive setae of spiders, these hairs are entirely smooth. At their base they are articulated in a socket with an asymmetrical groove that determines the direction of hair deflection. Hair shafts are up to 1000 m long. The exact grouping of smooth hairs in rows is typical of the coxae for each pair of legs. 2. Unlike the other, multiply innervated cuticular sensilla of spiders, smooth hairs are supplied by only a single mechanosensitive neuron. This is confirmed by electrophysiological recordings from single hairs. Threshold deflection to elicit a spike response lies near 1°. The response to maintained, step-like stimuli declines rapidly. 3. All central endings of these hair receptors in the fused segmental ganglia are confined to dorsal neuropil of the ipsilateral neuromere. The specific arborization pattern resembles an elongated, three-pronged fork with a long central prong. Topography, natural stimulus situation, and the phasic response characteristic of smooth hairs suggest that spiders use these sensilla to monitor the relative distance between leg coxae during locomotion.