Behavioral analysis of two distinct visual responses in the larva of the tiger beetle (Cicindela chinensis)

The tiger beetle larva shows two distinct visual responses, a predatory jump and an evasive withdrawal into the burrow (escape). In the present study the visual stimuli controlling these two responses have been behaviorally analyzed in the larva of Cicindela chinensis. The threshold size needed for a target to elicit both responses is a visual angle of 5–7°. The velocities of moving targets needed to elicit the responses are 0.4–33° s⁻¹ for the jump and 0.76–90° s⁻¹ for the escape. Choice between the two responses appears to be controlled by the actual target size rather than by the angular size. It also appears to be controlled by the target height. As the height of the target increases, the probability for the jump decreases, whereas the probability for the escape increases. Response properties of the larva with only a single functional stemma, the other stemmata being occluded, are different from those of the intact larva, which suggests cooperation of at least two stemmata for the release of different visual responses. Visual responses of the one-stemma larva still vary, however, with target size and target height, which suggests the visual responses are partially controlled even by a single stemma. Although our data do not resolve these conflicting results, more than one stemma is necessary for a firm choice between the two responses. Accepted: 13 May 1997     

Structure of the visual system of the larva of the tiger beetle (Cicindela chinensis)

The visual system of the larval tiger beetle (Cicindela chinensis) consists of six (two large, two mediumsized, and two small) stemmata on either side of the head, and an underlying neuropil mass. Each stemma exhibits a corneal lens and an underlying rhabdom layer. Retinular cells extend single proximal axons into the neuropil mass. The neuropil mass has a flattened heart-shape, and consists of two juxtaposed identical structures, each being a neuropil complex of each of the two large stemmata. The complex consists of lamina and medulla neuropils. Most retinular axons terminate in the lamina neuropil. Axons of two types of lamina monopolar neurons descend parallel to each other into the lamina neuropil. Moreover, each lamina neuropil contains a single giant monopolar neuron. Possible centrifugal processes and tangential neurons also occur. Lamina monopolar axons descend straight into the medulla neuropil. Medulla neurons spread fan-shaped dendrites distally in the medulla neuropil and send single axons toward the protocerebrum. These data are discussed with respecct to the unique visual behavior of this larva and in comparison with other insect visual systems.     

Visual determinants of escape in tiger beetle larvae (Cicindelidae)

Larvae of tiger beetles (Coleoptera: Cicindelidae) are burrow-dwelling, visual ambush predators which withdraw into their burrows with the passing of large objects. Laboratory experiments confirmed that stimulation of each of the four principal stemmata can elicit escape and that the necessary visual stimulus is contracting, expanding, or transverse movement of a high-contrast image. Response frequency increases as a power function of contrast. Whole-field dimming is ineffective. Movement of large images composed of multiple texture elements, e.g., checkerboards, does not elicit escape, even if each element is much larger than the system's minimum visible angle (4–8° depending upon image contrast). In pilot experiments with a single figure before a textured background, coherent movement of the two inhibits escape, whereas motion in opposite directions does not. Thus, the processing mechanism functions as a feature detector and directs a response to large, single, moving objects.     

Microhabitat segregation and physiological differences in co-occurring tiger beetle species,Cicindela oregona and Cicindela tranquebarica

Summary The daily movements of two co-occurring tiger beetle species were monitored in conjunction with changes in microclimate along streams in Northeast Arizona. Cicindela oregona and C. tranquebarica temporarily segregated across areas of beach exhibiting different microclimates. C. oregona progressively moved from the dry upper beach to the wet stream edge as beach temperatures increased and humidity decreased. The actively foraged throughout the day in this moist habitat at air temperatures between 25 and 38°C. C. tranquebarica remained on the dry, upper portions of the beach and shuttled between sun and shade at air temperatures above 35°C. Only when stream edge temperatures exceeded 30°C was tranquebarica found in this subhabitat. Both species exhibited physiological tolerances in the laboratory that were consistent with their microhabitat preferences in the field. Although both species had similar high lethal temperatures (47–48°C) in saturated air, oregona died at lower temperatures (39–43°C) than tranquebarica (46–47°C) under dry (0% RH) conditions. C. oregona was considerably more active than tranquebarica at body temperatures below 30°C and exhibited higher levels of active metabolism between 25 and 40°C. In addition, C. tranquebarica exhibited significantly lower water loss rates than oregona at 30, 35 and 40°C.     

Neural organization of the lamina neuropil of the larva of the tiger beetle (Cicindela chinensis)

Six neural elements, viz., retinular axons, a giant monopolar axon, straight descending processes (type I), lamina monopolar axons (type II), processes containing clusters of dense-core vesicles (type III), and processes coursing in various directions with varicosities (type IV), have been identified at the ultrastructural level in the lamina neuropil of the larval tiger beetle Cicindela chinensis. Retinular axons make presynaptic contact with all other types of processes. Type I and II processes possess many pre-and postsynaptic loci. Type II processes presumably constitute retinotopic afferent pathways. It remains uncertain whether type I processes are lamina monopolar axons or long retinular axons extending to the medullar neuropil. Type III processes may be efferent neurons or branches of afferent neurons contributing to local circuits. A giant monopolar axon extends many branches throughout the lamina neuropil; these branches are postsynaptic to retinular axons, and may be nonretinotopic and afferent. Type IV processes course obliquely in the neuropil, being postsynaptic to retinular axons, and presynaptic to type I processes.     

The synaptic organization of visual interneurons in the lobula complex of flies

Summary The synaptic organization of three classes of cobalt-filled and silver-intensified visual interneurons in the lobula complex of the blowfly Calliphora (Col A cells, horizontal cells and vertical cells) was studied electron microscopically. The Col A cells are regularly spaced, columnar, small field neurons of the lobula, which constitute a plexus of arborizations at the posterior surface of the neuropil and the axons of which terminate in the ventrolateral protocerebrum. They show postsynaptic specializations in the distal layer of their lobula-arborizations and additional presynaptic sites in a more proximal layer; their axon terminals are presynaptic to large descending neurons projecting into the thoracic ganglion. The horizontal and vertical cells are giant tangential neurons, the arborizations of which cover the anterior and posterior surface of the lobula plate, respectively, and which terminate in the perioesophageal region of the protocerebrum. Both classes of these giant neurons were found to be postsynaptic in the lobula plate and pre- and postsynaptic at their axon terminals and axon collaterals. The significance of these findings with respect to the functional properties of the neurons investigated is discussed.     

Circatidal rhythmic behaviour in the coastal tiger beetle Callytron inspecularis in Japan

Larvae of the coastal tiger beetle Callytron inspecularis (W. Horn) (Coleoptera: Cicindelidae) plug their burrow opening before submergence at high tide. Field observations showed that burrow plugging was a rhythmic behaviour that coincided with the tidal cycle (ca. 12.4 h). On average, larvae plugged their burrows 41.8 min before the tide covered the habitat. The mean interval between consecutive burrow-plugging events in the field was 12.40 h. In the laboratory, in the absence of tidal inundation, the mean interval between consecutive burrow-plugging events was 12.45 h. This suggests that the burrow-plugging rhythm of the coastal tiger beetle is governed by an endogenous circatidal rhythm.     

Responses of medulla neurons to illumination and movement stimuli in the tiger beetle larvae

Intracellular responses of medulla neurons (second-order visual interneurons) have been examined in the tiger beetle larva. The larva possesses six stemmata on either side of the head, two of which are much larger than the remaining four. Beneath the cuticle housing the stemmata an optic neuropil complex occurs consisting of lamina and medulla neuropils. Response patterns of medulla neurons to illumination and moving objects varied from neurons to neurons. For movement stimuli black discs and a black bar were moved in the rostro-caudal direction above the larva. Comparison of responses to the discs and the bar suggested a spatial summation of responses in some neurons, and tuning to small objects in some neurons. The majority of neurons responded to objects moving at heights of 10 mm and 50 mm with the same discharge pattern. A few neurons, however, showed distance sensitivities responding with an increase of spike discharges to moving objects only at either of the two heights. Such distance sensitivities still remained in one-stemma larvae, three of the four stemmata being occluded. These data are discussed in relation to distinct visual behavior of the larva and with special reference to perception of the hunting range.     

异色瓢虫视觉系统中5-HT阳性神经元的分布

本文运用树脂石蜡（Colophony-Paraffin,CP;专利号：ZL98125709．7）组织包埋切片技术,结合免疫组织化学链酶菌抗生物素蛋白一过氧化物酶（Streptavidin-Peroxidase,SP）双染法,对异色瓢虫视觉系统中5-羟色胺（5-HT）能神经元的分布进行了初步研究。结果显示,异色瓢虫视觉系统的结构及5-HT免疫反应系统相对比较特殊。5-HT阳性神经元胞体数目较少,染色显著,并聚集成群。根据胞体定位、细胞形态及轴突走向,可大体分为5群,其中包括1群呈弱反应的光感细胞。5-HT阳性膨大纤维支配所有的视神经纤维网,并呈柱状或分层排列模式。结果表明5-HT作为经典的神经递质在昆虫的视觉信息处理过程中可能发挥重要的调节作用,且主要以远距离的广域神经调节模式为主,并在特定区域和GABA有伴随现象。此外,昆虫视觉系统中5-HT的含量还可能与其明暗适应的生理调节方式具有相关性[动物学报51（5）：912—918,2005]。     

Morphological aspects of the third instar larva of Haematobia irritans

The main morphological features of the cephalic region of the larva of Haematobia irritans (L.) are the oral grooves, tripartite labium and the antennomaxillary protuberances that have the dorsal, terminal and ventral sensory organs. The total number of sensilla that are found on the terminal organ differs from other cyclorrhaphous-fly larvae. The fan-shaped anterior spiracles usually consist of seven bulbous digits that are unequal in length. The creeping welts consist of notched, convex plates that split into two separate plates as they approach the midline of the venter. This characteristic has not been described previously for this species or other, higher, dipterous larvae. There are two posterior spiracles with an ecdysial scar, four fan-shaped and branching spiracular hairs and irregularly-shaped spiracular openings. The longitudinal anal opening is situated in the cuticular band that is known as the anal organ.     

三点列黄边龙虱幼虫的呼吸系统与生物学特性

对龙虱幼虫的气门结构及体内气管、气囊的构造和分布进行了解剖、描述。通过饲养 ,对龙虱幼虫的栖境、食性、生长发育虫期、残杀性 ,化蛹等行为习性进行了较系统的观察研究。该虫在田间每年2代。     

柞蚕幼虫期神经系统一氧化氮合酶的NADPH-d组织化学

运用NADPH-d组织化学整体染色方法研究柞蚕Antheraea pernyi Gu rin-Meneville幼虫神经系统中一氧化氮合酶阳性细胞的分布、数量及形态特征。结果表明,柞蚕各龄期幼虫中枢神经的脑及各神经节中都有一氧化氮合酶阳性反应,阳性神经元根据其形态大小和染色特性可分为A,B,C3种类型:A型细胞沿神经节中线分布,阳性反应较强,胞体长径约30~70μm,各神经节中的数量恒定。B型细胞多分布于神经节周边部分,阳性反应较弱,胞体长径约8~20μm,各神经节中的数量变化较大,随着龄期增加有减少的趋势。C型细胞分布于咽下神经节和第8腹神经节,在3种细胞中阳性反应最强,胞体长径约16~50μm。     

韭菜迟眼蕈蚊幼虫消化系统的解剖学和组织学

本利用石蜡切片对韭菜迟眼蕈蚊幼虫其消化系统的组织学进行了研究。结果表明,幼虫的消化道无特殊变异,但中肠亚端部的一对胃盲囊长而发达,是消化道的突出特征。中肠和胃盲囊不同部位的细胞学特点有明显差异。根据中肠细胞形状及其分布将中肠分为4个区域,对中肠不同区域的细胞学特点进行了描述。     

Multimodal responses of the nonspiking giant interneurons in the brain of the crayfish Procambarus clarkii

Three pairs of nonspiking giant interneurons (NGIs; G1, G2, and G3) of the crayfish brain responded with depolarizing and hyperpolarizing graded potentials to body tilt in roll to the ipsi- and contralateral sides in the dark. The higher and the larger the angle of body tilt, the larger was the amplitude of the geotactic responses. In ipsilaterally statocystectomized animals, all the NGIs responded with hyperpolarizing potentials only to the contralateral side-down tilt, whereas in contralaterally statocystectomized animals, they responded with depolarizing potentials only to the ipsilateral side-down tilt. In bilaterally statocystectomized animals, none of the NGIs responded to body tilt in the dark, but in the presence of an overhead light, they exhibited depolarizing and hyperpolarizing potentials in response to body tilt to the ipsi-and contralateral sides, respectively. All the NGIs responded with depolarizing and hyperpolarizing graded potentials to illumination of the contra- and ipsilateral eyes, respectively. The amplitude of these visual responses, however, varied in association with the amplitude of the geotactic response produced by body tilt. These results indicate that the NGIs integrate the sensory inputs from eyes and statocysts and that the interaction between sensory inputs from the left and right sensory organs with either the same modality or with different modalities enhance the directional sensitivity of NGIs as premotoneurons in the compensatory oculomotor system.     

Differentiation of potassium currents in cultured inhibitory interneurons of the rat hippocampus (identification of the potassium M-type current)

Using a patch-clamp technique in the whole-cell configuration, we identified the potassium M-type current and estimated its contribution to the integral depolarization-induced potassium current evoked in cultured hippocampal inhibitory interneurons of the rat. With the help of immunocytochemical labeling, we checked the presence of the KCNQ-family channels responsible for generation of M current in these neurons. It was demonstrated that non-inactivated potassium channels and channels with slow kinetics play the main role in the processes of repolarization of the membrane of inhibitory interneurons. In all studied cells, a potassium current non-inactivated with time and possessing kinetic parameters close to those of the M current developed in response to depolarization. In all cells, positive immunocytochemical labeling with respect to KCNQ2 channels was observed; however, its intensity varied significantly from neuron to neuron. The level of suppression of non-inactivated potassium currents by a blocker of KCNQ channels, linopirdine, varied noticeably in different cells; therefore, the level of expression of these channels in the interneurons under study is probably considerably dissimilar. The reason for incomplete suppression of the M current is perhaps the involvement of other potassium channels (e.g., those of Kv1 family) in the formation of this current. Neirofiziologiya/Neurophysiology, Vol. 38, No. 3, pp. 198–204, May–June, 2006.     

Characterization of tactile-sensitive interneurons in the abdominal ganglia of the cockroach,Periplaneta americana

Tactile stimulation of an insect's abdomen evokes various behaviors including grooming and vigorous escape responses. We tested a sample of 37 tactile-sensitive abdominal interneurons for various morphological and physiological characteristics, including their ability to excite thoracic interneurons that are known to integrate wind information conducted by giant interneurons in the classical escape response. The results suggest that abdominal tactile-sensitive interneurons are heterogeneous both in anatomical and physiological properties. In general, these cells are very small interganglionic interneurons that respond to tactile stimulation at more than one abdominal segment. However, the larger population contained virtually all types of cells. Some projected anteriorly, others posteriorly, and still others projected in both directions. For most cells, the soma was on the side opposite to their axons, but in 24% of the cells it was on the same side. Patterns of dendritic arbors also varied among cells. However, tactile sensitivity was in general consistent with the morphological bias noted in dendritic branch patterns. We were able to document the existence of tactile abdominal interneurons that connect directly to thoracic interneurons involved in escape (TI_As). However, instances of demonstrated connectivity were rare. One cell that did show connectivity (AI652) was characterized in detail, and its properties were appropriate for conducting tactile signals in a directional escape system. The dendritic arbors were biased to the side that was ipsilateral to the cell's soma and axon. As a result, this cell's abdominal inputs and thoracic outputs are on the same side. This pattern is appropriate for generating the sensory fields recorded previously in TI_As. Its axon was located in the ventral median tract, which should bring it close to the integrating region of the TI_As. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 227–241, 1998     

Serotonin immunoreactivity in the nervous system of the Pandora larva, the Prometheus larva, and the dwarf male of Symbion americanus (Cycliophora)

Cycliophora is a recently described phylum of enigmatic metazoans with a very complex life cycle that includes several sexual and asexual stages. Symbion pandora and Symbion americanus are the only two cycliophoran species hitherto described, of which morphological and genetic knowledge is still deficient to clarify the phylogenetic position of the phylum. Aiming to increase the database on the cycliophoran neural architecture, we investigated serotonin immunoreactivity in the free swimming Pandora larva, the Prometheus larva, and the adult dwarf male of S. americanus. In the larval forms, serotonin is mainly expressed in a ring-shaped pattern at the periphery of the antero-dorsal cerebral ganglion. Additionally, several serotonergic perikarya emerge from both sides of the cerebral ganglion. Thin neurites project anteriorly from the cerebral ganglion, while a pair of ventral longitudinal neurites emerges laterally and runs along the anterior-posterior body axis. Posteriorly, the ventral neurites fuse and extend as a posterior projection. In the dwarf male, serotonin is found mainly in the commissural neuropil of the large anterior cerebral ganglion. In addition, serotonin immunoreactivity is present in the most anterior region of the ventral neurites. Comparative analysis of spiralian nervous systems demonstrates that the neuroanatomy of the cycliophoran larval stages resembles much more the situation of adult rather than larval spiralians, which may be explained by secondary loss of larval structures and heterochronic shift of adult components into the nervous system of the Pandora and the Prometheus larva, respectively.