Tonic effects of stationary luminous slits on the discharge rates of some locust visual interneurones

The presence of an illuminated slit in the visual field of a locust compound eye produced changes in the tonic discharge rate of the DCMD and three other visual interneurones, recorded in a connective. The DCMD discharge peaked initially in the range of low slit subtenses, but over a period of minutes of exposure its character changed so that there was a rise at high subtenses also. When the luminance of a slit of fixed subtense was increased in steps, there was an initial rise then a sharp fall in discharge, indicating an abrupt onset of inhibition. Lateral spread of inhibition could account for the peak in response to slits, at a subtense falling well within the acceptance angle of a single ommatidium. The results show the ability of some visual interneurones to maintain a changed level of discharge in the presence of a stationary object in the visual field of the eye.     

Peaking of response in locust visual interneurones to objects of small angular subtense

One compound eye of an immobilised locust viewed a large screen on to which were projected discs of light for periods of 2 sec every 40 sec. The spike response was counted concurrently in the DCMD and the next largest axon in the contralateral nerve cord connective. The average score for 10 trials, after correction for background was plotted for a series of discs subtending a range of angles from 0.05 to 84°.It was found that the response of the DCMD peaked sharply and consistently at a subtense of 0.3°, and fell away to a low plateau or to zero over the range 2° to 84°. The response could exceed background down to subtenses as low as 0.05° (3′ of arc). The response of the next largest axon also showed an early peak, but it was inhibitory and resembled a mirror image of that of the DCMD, although it did not always coincide, ranging from 0.2 to 0.3°. The response, by contrast with the DCMD, rose to a high level at large subtenses, forming a flat peak.No explanation in optical terms could be found for this peaking at small subtenses, and a scheme is proposed by which a peak response could develop by the interaction of excitatory and inhibitory processes in the optic lobe.The peak value of 0.3° corresponds with the resolution limit for moving periodic patterns repeatedly demonstrated by Burtt and Catton (e.g. 1962, 1969). Such peaking behaviour would serve to lift the response curve of the whole visual system at high spatial frequencies, and thus extend the resolution limit.With stepwise reduction in intensity of a small luminous target there was a steep fall in the DCMD response, but a similar reduction for a large target had only a small effect. This could be explained by assuming that excitatory processes were prevalent for small targets, subtending about 0.3°, whereas for larger targets the excitatory and inhibitory processes came into balance over a wide range of intensities, thereby stabilising the response, at a low level.     

The effects of stimulus area and intensity on the on/off ratio of some locust visual interneurones

The on- and off-discharges of three types of locust visual interneurones were recorded in response to luminous discs ranging in subtense from 0.4 to 25°. For the DCMD neurone there was a clear reciprocal relationship between ON and OFF, with large on- and small off-responses at 0.4°, and the reverse at 25° disc subtense. Most of the changeover from almost pure ON to almost pure OFF discharges occurred in the subtense range up to 2°, i.e. within the acceptance angle of one ommatidium or the angle between adjacent ommatidia. This behaviour was not found at low luminance levels, where ON and OFF followed parallel courses. These findings suggest the existence of strong inhibition, augmenting rapidly with increase in target subtense, as also with luminance as shown in separate experiments. For the DCMD the off-response had the characteristics of a simple rebound excitation, following a short period of light exposure.The other visual interneurones (M and S) behaved differently. They did not show reciprocity of ON and OFF, but instead their responses followed parallel courses with increase in subtense, resembling those of the DCMD at low luminance. Nonetheless, like the DCMD, they did show peaking of the on-response at certain subtenses and luminance, although at much higher levels. The inhibitory activity defining the responses of M and S neurones appeared much less effective than that associated with the DCMD. This could be due to greater complexity in their central connexions, of which nothing is known.     

Long-term survival followed by degradation of neurofilament proteins in severed Mauthner axons of goldfish

The morphology and protein composition of intact and severed Mauthner axons (M-axons) from goldfish were examined on electron micrographs, sodium dodecyl sulfate gels, and immunoblots. Neurofilaments were the most common cytoskeletal element on electron micrographs, and neurofilament proteins (NFPs) were the most intensely silver-stained bands in M-axoplasm microdissected from control M-axons. NFPs at about 235, 145, 123, 105, 80, and 60 kD in M-axoplasm were identified with four monoclonal and three polyclonal antibodies. Similar immunoblots of samples of the M-axon myelin sheath (M-sheath) showed no reactivity to antibodies against NFPs. For up to 62 days following spinal cord severance in goldfish maintained at 15°C, the ultrastructure, protein banding pattern, and anti-NFP immunoreactivity of severed distal segments of M-axons did not change compared with control M-axons. At 62 to 81 days after severance, novel bands appeared in many silver-stained gels and anti-NFP immunoblots of distal M-axons. NFP bands completely disappeared from distal M-axon segments of some M-axons as early as 72 days after severance. However, NFP bands persisted in some distal segments for up to 81 days after severance. The degradation of NFPs occurred equally along the entire length of a distal M-axon segment, that is, there was no indication of a proximal-to-distal or distal-to-proximal sequence of NFP degradation in distal segments of severed M-axons. These biochemical data were consistent with morphological data that showed little change in the diameter or ultra-structure of severed M-axons held at 15°C for about 2 months followed by a rapid collapse of the entire distal segment at 72 to 85 days postseverance. 1994 John Wiley & Sons, Inc.     

Model studies on the mechanical significance of grouping in compound spider slit sensilla (Chelicerata,Araneida)

Summary The mechanical implications of various types of slit arrangements found among the strain-sensitive slit sensilla in the arachnid exoskeleton (Fig. 3) were studied by measuring the deformation of model slits, cut into plastic discs, under static load applied in the plane of the disc and from varying directions (Figs. 1, 2).1. Close parallel, lyriform arrangements. Compression of slits (adequate stimulus) reaches much higher values than dilatation. It is highest with the load direction at right angle to the slit axes. Also, in the majority of slits the range of load angles resulting in compression is considerably larger than that leading to dilatation. Length distribution and lateral shift of slits in the models have a pronounced effect on slit deformability (Figs. 4-5): (a) In the oblique bar arrangement with slits of equal length and regular lateral shift (Fig. 4A) deformation of all slits is very similar at all load directions. In all slits compression results from a range of load angles larger than 120°. (b) In arrangements with a regular increase in slit length and a triangular outline shape deformability differs greatly among the slits at all load angles (Fig. 4B). (c) The slit configuration with a heartshaped outline (Fig. 4C) is peculiar for the large spread of load angles at which the compression of the different slits is highest. — These properties recommend different arrangements for the solution of different strain measuring problems, with for instance, the particular need of a wide angular working range (arrangement a), of a large spectrum of absolute sensitivities (b), or of the analysis of load direction (c).2. Angle and distance between slits. Due to the mechanical directionality inherent in an elongated slit the divergence of slit axes within a group of slits is likely to indicate the importance of the analysis of strain direction (Fig. 6). The mechanical interaction between closely neighbouring slits decreases with their distance from each other. In a parallel arrangement of equally long slits it disappears if the distance is about 1.5 times the slit length (Fig. 7).3. Aiming towards a mechanical model which would explain the complex deformation found in a lyriform organ, we consider the outline of the organ as a hole traversed by beams of material. Slit deformation can be calculated from the elastic lines of the beams which separate the slits and information drawn from photoelastic experiments (Figs. 8-11).     

Tests of the limiting visual resolution of the DCMD system of the lubber grasshopper to rectangular gratings

Visual acuity measurements using the descending contralateral movement detector (DCMD) neuron in the lubber grasshopper, Romalea microptera, show responses to spatial angles as small as 0.3°. Moving, black-white striped objects were viewed on a rear-projection screen.Nonuniformity and spatial sub-harmonic measurements of the object patterns showed that any artifacts which were present were below the resolution limits of the human visual system (and presumably that of Romalea).Nonstationarity in the responses of the DCMD system can be categorized as long-term (sensitivity changes) and short term (habituation). A mathematical model for habituation is used to illustrate how confidence in responses may be lost due to the incorporation of too many samples of habituated data.     

Invasion of microglia/macrophages and granulocytes into the Mauthner axon myelin sheath following spinal cord injury of the adult goldfish,Carassius auratus

Rapid activation of resident glia occurs after spinal cord injury. Somewhat later, innate and adaptive immune responses occur with the invasion of peripheral immune cells into the wound site. The activation of resident and peripheral immune cells has been postulated to play harmful as well as beneficial roles in the regenerative process. Mauthner cells, large identifiable neurons located in the hindbrain of most fish and amphibians, provided the opportunity to study the morphological relationship between reactive cells and Mauthner axons (M-axons) severed by spinal cord crush or by selective axotomy. After crossing in the hindbrain, the M-axons of adult goldfish, Carassius auratus, extend the length of the spinal cord. Following injury, the M-axon undergoes retrograde degeneration within its myelin sheath creating an axon-free zone (proximal dieback zone). Reactive cells invade the wound site, enter the axon-free dieback zone and are observed in the vicinity of the retracted M-axon tip as early as 3 hr postinjury. Transmission electron microscopy allowed the detection of microglia/macrophages and granulocytes, some of which appear to be neutrophil-like, at each of these locations. We believe that this is the first report of the invasion of such cells within the myelin sheath of an identifiable axon in the vertebrate central nervous system (CNS). We speculate that microglia/macrophages and granulocytes that are attracted within a few hours to the damaged M-axon are part of an inflammatory response that allows phagocytosis of debris and plays a role in the regenerative process. Our results provide the baseline from which to utilize immunohistochemical and genetic approaches to elucidate the role of non-neuronal cells in the regenerative process of a single axon in the vertebrate CNS.     

Finite element modeling of arachnid slit sensilla: II. Actual lyriform organs and the face deformations of the individual slits

Arachnid slit sensilla respond to minute strains in the exoskeleton. After having applied Finite Element (FE) analysis to simplified arrays of five straight slits (Hößl et al. J Comp Physiol A 193:445–459, 2007) we now present a computational study of the effects of more subtle natural variations in geometry, number and arrangement of slits on the slit face deformations. Our simulations show that even minor variations in these parameters can substantially influence a slit’s directional response. Using white-light interferometric measurements of the surface deformations of a lyriform organ, it is shown that planar FE models are capable of predicting the principal characteristics of the mechanical responses. The magnitudes of the measured and calculated slit face deformations are in good agreement. At threshold, they measure between 1.7 and 43 nm. In a lyriform organ and a closely positioned loose group of slits, the detectable range of loads increases to approximately 3.5 times the range of the lyriform organ alone. Stress concentration factors (up to ca. 29) found in the vicinity of the slits were evaluated from the models. They are mitigated due to local thickening of the exocuticle and the arrangement of the chitinous microfibers that prevents the formation of cracks under physiological loading conditions.     

In search of differences between the two types of sensory cells innervating spider slit sensilla (<Emphasis Type="Italic">Cupiennius salei</Emphasis> Keys.)

The metatarsal lyriform organ of the spider Cupiennius salei is a vibration detector consisting of 21 cuticular slits supplied by two sensory cells each, one ending in the outer and the other at the inner slit membrane. In search of functional differences between the two cell types due to differences in stimulus transmission, we analyzed (1) the adaptation of responses to electrical stimulation, (2) the thresholds for mechanical stimulation and (3) the representation of male courtship vibrations using intracellular recording and staining techniques. Single- and multi-spiking receptor neurons were found among both cell types, which showed high-pass filter characteristics. Below 100-Hz threshold, tarsal deflections were between 1° and 10°. At higher frequencies, they decreased down to values as small as 0.05°, corresponding to 4.5-nm tarsal deflection in the most sensitive cases. Different slits in the organ and receptor cells with slow or fast adaptation did not differ in this regard. When stimulated with male courtship vibrations, both types of receptor cells again did not differ significantly regarding number of action potentials, latency and synchronization coefficients. Surprisingly, the differences in dendrite coupling were not reflected by the physiological responses of the two cell types innervating the slits.     

Temperature-sensitive gating in a descending visual interneuron, DCMD

Activity in neural circuits can be modified through experience-dependent mechanisms. The effects of high temperature on a locust visual interneuron (the descending contralateral movement detector, DCMD) have previously been shown to be mitigated by prior exposure to sub-lethal, elevated temperatures (heat shock, HS). Activity in the DCMD is reduced at high temperature in naïve animals (control), whereas HS animals show a maintained spike count at all temperatures. We examined whether this finding was due to direct effects of temperature on visual processing, or whether other indirect feedback mechanisms were responsible for the observed effect in the DCMD. Activity in the DCMD was elicited using a computer-generated looming image, and the response was recorded extracellularly. The temperature of visual processing circuits contributes directly to HS-induced plasticity in the DCMD, as maintaining the brain at 25°C during a thoracic temperature ramp eliminated the high frequency activity associated with HS. Removing ascending input by severing the thoracic nerve cord reduced DCMD thermosensitivity, indicating that indirect feedback mechanisms are also involved in controlling the DCMD response to increased thoracic temperature. Understanding how thermosensitive feedback within the locust affects DCMD function provides insight into critical regulatory mechanisms underlying visually-guided behaviors.     

On the Ultrastructure and Function of Rhogocytes from the Pond Snail Lymnaea stagnalis

Rhogocytes, also termed “pore cells”, occur as solitary or clustered cells in the connective tissue of gastropod molluscs. Rhogocytes possess an enveloping lamina of extracellular matrix and enigmatic extracellular lacunae bridged by cytoplasmic bars that form 20 nm diaphragmatic slits likely to act as a molecular sieve. Recent papers highlight the embryogenesis and ultrastructure of these cells, and their role in heavy metal detoxification. Rhogocytes are the site of hemocyanin or hemoglobin biosynthesis in gastropods. Based on electron microscopy, we recently proposed a possible pathway of hemoglobin exocytosis through the slit apparatus, and provided molecular evidence of a common phylogenetic origin of molluscan rhogocytes, insect nephrocytes and vertebrate podocytes. However, the previously proposed secretion mode of the respiratory proteins into the hemolymph is still rather hypothetical, and the possible role of rhogocytes in detoxification requires additional data. Although our previous study on rhogocytes of the red-blooded (hemoglobin-containing) freshwater snail Biomphalaria glabrata provided much new information, a disadvantage was that the hemoglobin molecules were not unequivocally defined in the electron microscope. This made it difficult to trace the exocytosis pathway of this protein. Therefore, we have now performed a similar study on the rhogocytes of the blue-blooded (hemocyanin-containing) freshwater snail Lymnaea stagnalis. The intracellular hemocyanin could be identified in the electron microscope, either as individual molecules or as pseudo-crystalline arrays. Based on 3D-electron microscopy, and supplemented by in situ hybridization, immunocytochemistry and stress response experiments, we provide here additional details on the structure and hemocyanin biosynthesis of rhogocytes, and on their response in animals under cadmium and starvation stress. Moreover, we present an advanced model on the release of synthesized hemocyanin molecules through the slit apparatus into the hemolymph, and the uptake of much smaller particles such as cadmium ions from the hemolymph through the slit apparatus into the cytoplasm.     

Host-foraging stable flies,Stomoxys calcitrans,are preferentially attracted to objects with both visual and thermal host-like characteristics

Many haematophagous insects use the heat emitted by warm-blooded animals as a cue for locating suitable hosts. Blood-feeding stable flies, Stomoxys calcitrans (L.) (Diptera: Muscidae), are known to respond to visual and olfactory host cues. However, the effects of thermal host cues on the foraging behaviour of these flies remain largely unknown. Here we tested the hypothesis that host-foraging stable flies preferentially land on objects with host-like temperature, and on objects with both visual and thermal host-like cues. In laboratory bioassays, stable flies were offered a choice between paired temperature-controlled copper discs. Flies preferentially landed on the disc with a host-like temperature (40 °C), discriminating against discs that were cooler (26 or 35 °C) or warmer (50 or 60 °C) than vertebrate hosts. Flies that were well fed and thus not in foraging mode, or host-foraging flies that were offered infrared radiation but not the conductive and convective heat of different temperature discs, failed to discriminate between the stimuli. In greenhouse experiments, when flies were offered a choice between paired barrels as surrogate hosts, flies preferentially landed on barrels that were both thermally and visually appealing (38–39 °C, black), discriminating against barrels that were cold (10 °C), white, or both cold and white. Thermal cues augmented the overall landing responses of flies but their initial (mid-range) attraction to barrels was mediated by visual cues. Overall, the data suggest that thermal host cues affect the host-foraging behaviour of stable flies primarily at close range, prompting landing on a host.     

Predicted performance of single- versus multiple-slit flow systems.

Flow systems utilizing multiple orthogonal excitation slits have been proposed as a means of reducing some types of false alarms in prescreening systems for gynecologic cytology. Such false alarms include those caused by orientation-dependent events, such as passage of binucleate or overlapping cells through the measurement region with both nuclei entering the excitation slit simultaneously. This paper presents distributions of optimal projection angles for randomly oriented nuclei passing through one, two, and three slit excitation regions. The results are used to compute observed nuclear spacing of binucleate cells and to compare performance of one, two, and three slit systems in recognition of binucleate and overlapping cells.     

Studying the deformation of arachnid slit sensilla by a fracture mechanical approach

Slit sensilla are sensory organs which measure strains in the exoskeleton of arachnids. They occur as isolated slits, in loose groups and in close parallel arrangements known as lyriform organs or compound slit sensilla. The deformations of the slits' faces induced by far-field strains acting on groups of slits are studied using Kachanov's analytical approximations for the opening displacements of cracks, a method developed within the framework of fracture mechanics. The accuracy of the approach is assessed by comparisons with results obtained by finite element analysis. The limits of its applicability to slit sensilla are found to be reached when the lateral spacing between interacting slits is less than half their length, i.e., the method is suitable for studying single slits and loose groups but not lyriform organs. The influence of a number of geometrical parameters of slit sensilla on the deformation patterns of the faces of parallel slits in generic arrangements is studied, viz., spacing between slits, longitudinal shifts between slits, and slit length. The results are presented as opening distances along the length of the cracks and in terms of normalized diagrams that relate the opening distances at mid-length of the slits to the geometrical parameters. In addition, Kachanov's method is used to find a set of slit lengths that give rise to prescribed opening distances.     

Histology of melanic flank and opercular color pattern elements in the firemouth cichlid,Thorichthys meeki

Dark melanic color pattern elements, such as bars, stripes, and spots, are common in the skin of fishes, and result from the differential distribution and activity of melanin‐containing chromatophores (melanophores). We determined the histological basis of two melanic color pattern elements in the integument of the Firemouth Cichlid, Thorichthys meeki. Vertical bars on the flanks were formed by three layers of dermal melanophores, whereas opercular spots were formed by four layers (two lateral and two medial) in the integument surrounding the opercular bones. Pretreatment of opercular tissue with potassium and sodium salts effectively concentrated or dispersed intracellular melanosomes. Regional differences in epidermal structure, scale distribution, and connective tissues were also identified. J. Morphol. 2013. © 2013 Wiley Periodicals, Inc.     

Preparing for escape: an examination of the role of the DCMD neuron in locust escape jumps

Many animals begin to escape by moving away from a threat the instant it is detected. However, the escape jumps of locusts take several hundred milliseconds to produce and the locust must therefore be prepared for escape before the jumping movement can be triggered. In this study we investigate a locust’s preparations to escape a looming stimulus and concurrent spiking activity in its pair of uniquely identifiable looming-detector neurons (the descending contralateral movement detectors; DCMDs). We find that hindleg flexion in preparation for a jump occurs at the same time as high frequency DCMD spikes. However, spikes in a DCMD are not necessary for triggering hindleg flexion, since this hindleg flexion still occurs when the connective containing a DCMD axon is severed or in response to stimuli that cause no high frequency DCMD spikes. Such severing of the connective containing a DCMD axon does, however, increase the variability in flexion timing. We therefore propose that the DCMD contributes to hindleg flexion in preparation for an escape jump, but that its activity affects only flexion timing and is not necessary for the occurrence of hindleg flexion.     

Filter feeding,deviations from bilateral symmetry,developmental noise,and heterochrony of hemichordate and cephalochordate gills

We measured gill slit fluctuating asymmetry (FA), a measure of developmental noise, in adults of three invertebrate deuterostomes with different feeding modes: the cephalochordate Branchiostoma floridae (an obligate filter feeder), the enteropneusts Protoglossus graveolens (a facultative filter feeder/deposit feeder) and Saccoglossus bromophenolosus (a deposit feeder). FA was substantially and significantly low in B. floridae and P. graveolens and high in S. bromophenolosus. Our results suggest that the gills of species that have experienced a relaxation of the filter feeding trait exhibit elevated FA. We found that the timing of development of the secondary collagenous gill bars, compared to the primary gill bars, was highly variable in P. graveolens but not the other two species, demonstrating an independence of gill FA from gill bar heterochrony. We also discovered the occasional ectopic expression of a second set of paired gills posterior to the first set of gills in the enteropneusts and that these were more common in S. bromophenolosus. Moreover, our finding that gill slits in enteropneusts exhibit bilateral symmetry suggests that the left‐sidedness of larval cephalochordate gills, and the directional asymmetry of Cambrian stylophoran echinoderm fossil gills, evolved independently from a bilaterally symmetrical ancestor.     

Auditory acuity in the orientation behaviour of the bushcricket Pachysagella australis walker (Orthoptera,Tettigoniidae, Saginae)

The female tettigoniid Pachysagella australis (Saginae) orients to the call of the conspecific with an angular acuity of ±5°. This acuity is mediated by sound entering to the tympanic receptors through the auditory trachea and the slits exterior to the tympanic membranes. The phonokinetic response of females was filmed in an arena. The slit system was blocked on both anterior and posterior ports with the effect that the female spiralled towards the sound source; blocking the posterior slit alone reduced the auditory acuity as did the partial occlusion of the fore slit, but in both cases the female located the male. Complete blocking of the auditory spiracle caused the insect to spiral towards the unoperated side, whereas reducing the sound input to one side by some 8–12 dB, by plugging the auditory bulla with compacted cotton wool, did not substantially affect the orientation pattern of the insect. Ablation of the tympanic organ on one side caused the female to move in a circular pattern to the unoperated side. A hypothesis is formulated whereby the female, when actively orienting to the calling male, may use the slit port system to gain a high degree of auditory acuity to sound in front of her body axis. When off target she may use the less accurate spiracular input system. This system, with its greater sensitivity to high frequency sounds, may function as an effective anti-predator warning system.     

Ein atlas der spaltsinnesorgane von Cupiennius salei keys. Chelicerata (Araneae)

To facilitate further physiological investigation, a survey was undertaken of all the slit sense organs to be found on the body of the spider Cupiennius salei. We counted and mapped more than 3 000 sensory slits in the cuticle about half of which are combined to small groups of up to 29 slits forming compound or lyriform organs.