Fine structure of the first optic ganglion (lamina) of the cockroach, Periplaneta americana

The structural organization of the first optic ganglion (lamina) of the cockroach (Periplaneta americana) was investigated by the use of light and electron microscopy. Each compound eye of the cockroach is composed of up to 2000 visual units (ommatidia) of the fused rhabdom type. The ommatidia themselves consist of eight receptor cells which terminate as axons in either the first or second optic ganglion. Three different short visual fibre types end in two separate strata in the lamina, and one long fibre type ends in the second optic ganglion. Monopolar second-order neurons with wide field branching patterns in the middle stratum of the first synaptic region have postsynaptic contacts with short visual fibres. Horizontal fibre elements with branching patterns at different levels of the lamina apparently form three horizontal plexuses with presynaptic and/or postsynaptic connections to first- and secondorder neurons. The lack of well-organized fibre cartridges containing a constant number of first and second order neurons in each fascicle and the presence of only unistratified wide field monopolar cells could represent, as compared to other insect orders, a primitive stage in the development of the first optic ganglion.     

Multisegmental cobalt filling of the dorsal giant fibers in the nervous system of the earthworm,Lumbricus terrestris

Summary The anatomical organization of the two dorsal giant fiber systems of the earthworm Lumbricus terrestris is demonstrated in whole mounts and serial-section reconstructions based on backfillings of the ventral nerve cord with cobalt chloride. Both the medial and lateral fiber systems can be labeled selectively over more than ten body segments. They show a characteristic segmental pattern of collaterals with some modification in tail segments and of dorsal plasma protrusions in the unpaired medial giant fiber presumably representing openings in the myelin sheath. We found no multisegmental cobalt transport in other large neurons of the nerve cord. Cobalt passes through the segmentai septa between consecutive axonal elements of the metameric giant fibers and presumably also through commissural contacts between specific collaterals of the lateral giant fibers. Since these sites of contact are known to represent electrical synapses, cobalt coupling may, in L. terrestris, correlate with functional electrotonic coupling.Abbreviations CL collateral of lateral giant fiber - CM collateral of medial giant fiber - GIN giant interneuron - LGF lateral giant fiber - MGF medial giant fiber - SN segmental nerve     

Dynamic aspects of retinotectal map formation revealed by a vital-dye fiber-tracing technique

In the visual system of Xenopus laevis, the axons from the retinal ganglion cells of the eye form a topographic projection onto the optic tectum. Many studies have focused on revealing the mechanisms responsible for this precise and regular projection pattern. In contrast to the static view of the system that one might expect from examining the regularity of the projection, recent work on its regeneration and its changes during larval development indicate that part of the patterning process involves the dynamic behavior of optic fibers. Typically, anatomical and electrophysiological techniques have been used to obtain static views of the developing retinotectal projection which then must be complied to provide a glimpse of any dynamic behavior. Here we report on experiments using a newly developed fiber tracing technique to directly follow the emergence of topography in the developing retinotectal projection. Defined halves of the developing eyebud were labeled with a vital fluorescent dye which fills the growing axons, and the projection of the labeled cells was followed for up to 2 weeks in individual animals. The experiments confirm that dorsal and ventral optic nerve fibers sort out into an ordered projection early in development. In contrast, nasal and temporal fibers initially overlap, and the same sets of prelabeled fibers then sort out into the adult topography over a period of days.     

The organization of the lamina ganglionaris of the hemipteran insects,Notonecta glauca,Corixa punctata and Gerris lacustris

Summary Neuronal elements, i.e. first and second order neurons, of the first optic ganglion of three waterbugs, N. glauca, C. punctata and G. lacustris, are analyzed on the basis of light and electron microscopy.Eight retinula cell axons, leaving each ommatidium, disperse to different cartridges as they enter the laminar outer plexiform layer. Such a pattern of divergence is one of the conditions for neuronal superposition; it is observed for all three species of waterbugs. The manner in which the receptors of a single bundle of ommatidia split of within the lamina, whereby information from receptors up to three or five horizontal rows away can converge upon the same cartridge, differs among the species. Six of the eight axons of retinula cells R1-6, the short visual fibers end at different levels within the bilayered lamina, whereas the central pair of retinula cells R7/8, the long visual fibers, run directly through the lamina to a corresponding unit of the medulla. Four types of monopolar cells L1–L4 are classified; their branching patterns seem to be correlated to the splitting and termination of retinula cell axons. The topographical relationship and synaptic organization between retinula cell terminals and monopolar cells in the two laminar layers are identified by examination of serial ultrathin sections of single Golgi-stained neurons.An attempt is made to correlate some anatomical findings, especially the neuronal superposition, to results from physiological investigations on the hemipteran retina.     

Larval size constraints determine directional ontogenetic shifts in the visual system of teleosts1

We summarize characteristic sequences of morphological change in the teleost visual system from larvae to large adults at the level of the retina, the optic tract and the optic tectum. These shifts include sizes and ratios of cone and rod receptor cells, sizes and types of retinal ganglion cells and optic tract fibers as well as features of the optic tectum. Teleost larvae are the smallest vertebrates known. We suggest that the utilization of color contrasts as an adaptive benefit dictates the starting point of morophological development, which is a pure cone retina in most fish larvae. The direction of morphological and functional shifts in the teleost visual system during growth is determined by continuous retinal stretch, which allows for improving visual abilities. The larval visual system probably provides just adequate photopic (cone-)acuity for plankton feeding, but limited space in the retina hampers optimization of both, photopic resolving power and sensitivity Limited space also Irevents the simultaneous development of the scotopic (rod-)system. Over a wide range of body sizes, morphological parameters change, photopic and scotopic resolving power, acuity and sensitivity improve. Size constraints in the teleost visual system and lifefong shifts in sensory capacities are discussed with respect to ecology and the niche concept.     

First-occupancy model for signal transfer in the brain

In rats and rabbits, optic nerve fibers are asymmetrically decussated. Evoked bioelectric signal/noise power ratio as a function of decussation ratio afferent to the lateral geniculate and thence to visual cortex conforms approximately to what one would expect if the visual system functioned as a parallel coherent detector. Brain mechanisms which can quantitatively account for these findings have not been previously proposed. A theoretical model is proposed to explain observed bioelectric input-output relationships in asymmetrically decussated visual systems and to suggest a general mechanism for signal transfer in the mammalian brain. The model is stochastic and is based upon earlier work concerning coherent neuronal activity. A specific quantitative implication of the model is that, on the average, three ganglion cells in the retina will drive each principal cell in the lateral geniculate. This prediction of the model is verified by recent experimental findings.     

A study of the cerebral region of the visual system in the pulmonata

The distribution of central axons of receptor cells of the eyes and the locations of neurons sending axons into the optic nerves were studied in the cerebral ganglia of the pulmonate mollusksLymnaea stagnalis andHelix sp. by the method of axonal transport of cobalt chloride injected via the optic nerves. Afferent fibers of these nerves form terminal ramifications (chiefly dorsally) in the middle part of the cerebral ganglion. Some of them pass through the commissure to the symmetrical region of the opposite cerebral ganglion. Neurons innervating the eyes are located in several regions of both cerebral ganglia. InLymnaea they are distributed near the point of entry of the optic nerve, in the region of the commissure, the mesocerebrum, and the posterior part of the ganglion. InHelix these neurons are found in the same regions except in the posterior part of the ganglion. In electrophysiological experiments responses of neurons in these parts of the cerebral ganglion to adequate stimulation of the eye were recorded. Differences in the character of responses and also the presence of neurons indifferent to stimulation of the eye are evidence of the functional heterogeneity of these areas. This suggests that morphologically separate visual centers do not exist in the cerebral ganglion of the Pulmonata. Neurons giving specific responses to stimulation of the eye and evidently belonging to different levels of the visual system (afferent or efferent divisions) are closely connected both with each other and with cells of other functional systems.A. A. Ukhtomskii Physiological Research Institute, A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 14, No. 2, pp. 179–184, March–April, 1982.     

On the problem of retinal transmitters of the freshwater mollusc <Emphasis Type="Italic">Lymnaea stagnalis</Emphasis>

Retrograde staining of retina of Lymnaea stagnalis with neurobiotin demonstrated that most photoreceptor cells send axons to the optic nerve directly, without intermediate contacts. Some of the photoreceptors are glutamate-immunoreactive suggesting that glutamate can provide the synaptic transmission of visual signal to the central neurons. Other photoreceptors stained via optic nerve seem to have other transmitter systems. Some of the retinal cells, but not the optic nerve fibers are pigment-dispersing hormone-immunoreactive. There are many serotonin-containing fibers in the tissue surrounding the optic cup with some of them penetrating the basal lamina of retina. Some of them belong to central neurons providing efferent innervation of the pond snail eye. Serotonergic innervation as well as pigment-dispersing hormone-containing cells are supposed to be involved in mechanism of the photosensitivity regulation of the molluscan eye.     

The superposition eye of Cloeon dipterum: The organization of the lamina ganglionaris

Summary The lamina ganglionaris of the superposition eye of Cloeon dipterum is composed of separate optic cartridges arranged in a hexagonal pattern. Each optic cartridge consists of one central, radially branched monopolar cell (Li) surrounded by a crown of seven retinula cell terminals and two more unilaterally branched monopolar cells (La1/La2) situated close together outside the cartridge. Projections to neighbouring cartridges have not been observed.In most cases, synaptic contacts could be seen between a presynaptic retinula cell and more than two other postsynaptic profiles, which belong to monopolar cells or sometimes to glial cells.Seven retinula cell fibers of one ommatidium pass in a bundle through the basement membrane, run into their respective cartridges without changing orientation and terminate at approximately equal levels in the lamina. Long visual fibers with endings in the medulla are not visible in the superposition eye lamina, but are present in the lateral apposition eye. The relationship between the behaviour of the animal, optic mechanisms of the superposition eye and the structure of the lamina is discussed.     

Cholinergic and GABAergic neuronal elements in the pineal organ of lampreys, and tract-tracing observations of differential connections of pinealofugal neurons

The putative cholinergic and GABAergic elements of the pineal organ of lampreys were investigated with immunocytochemistry to choline acetyltransferase (ChAT) and γ-aminobutyric acid (GABA), and by acetylcholinesterase (AChE) histochemistry. For comparison we also carried out immunocytochemistry to serotonin (5-HT) and a tract-tracing investigation of the two types of projecting cells, i.e., ganglion cells and long-axon photoreceptors. Most photoreceptors were ChAT-immunoreactive (ChAT-ir) and AChE-positive, while ganglion cells and the pineal tract were ChAT-negative and AChE-negative or only faintly positive. These results strongly suggest the presence of a cholinergic system of photoreceptors in the lamprey pineal organ. GABA-ir fibers that appear to originate from faintly to moderately stained ganglion cells were observed in the pineal stalk. Immunocytochemistry to 5-HT indicated the presence of two types of 5-HT-ir cells, bipolar cells and ganglion-like cells. The connections of the ganglion cells and long-axon photoreceptors were also studied by application of DiI to the pineal stalk in fixed brains or of biotinylated dextran amine (BDA) to one of the main targets of pinealofugal fibers (optic tectum or mesencephalic tegmentum) in isolated brains in vitro. Some long-axon photoreceptors and ganglion cells were labeled from the optic tectum. However, BDA application to the tegmentum exclusively labeled ganglion cells in the pineal organ. These results indicate that the two morphological types of afferent pineal neuron have different projections. No labeled cells were observed in the parapineal organ in BDA experiments, indicating that this organ and the pineal organ are involved in different neural circuits.     

Distribution and functional significance of Met-enkephalin-Arg6-Phe7- and Met-enkephalin-Arg6-Gly7-Leu8-like peptides in the blowfly Calliphora vomitoria

Summary Neuronal pathways immunoreactive to antisera against the extended-enkephalins, Met-enkephalin-Arg⁶-Phe⁷ (Met-7) and Met-enkephalin-Arg⁶-Gly⁷-Leu⁸ (Met-8), have been identified in the brain of the blowfly Calliphora vomitoria. Co-localisation with other enkephalins in certain neurons suggests that a precursor similar to preproenkephalin A exists in insects and that differential enzymatic processing occurs as in vertebrates. Co-localisations of the extended-enkephalin-like peptides with other vertebrate-type peptides, including cholecystokinin and pancreatic polypeptide, also occur. The enkephalinergic pathways are specific, comprising a few groups of highly characteristic neurons and areas of neuropil. Of special interest is the finding that parts of the antennal chemosensory and the optic lobe visual systems contain Met-8 immunoreactive neurons. Within the median neurosecretory cell groups, some of the giant neurons show immunoreactivity to Met-8 and others to both Met-8 and Met-7. Fibres from these cells project to the corpus cardiacum and also to the suboesophageal ganglion, where arborisations occur in the tritocerebral neuropil. Co-localisation studies of these cells have shown that at certain terminals, one particular type of peptide is the dominant neuroregulator, whilst at other terminals, within the same cell, a different co-synthesised peptide predominates. Several groups of lateral neurosecretory cells show clearly defined enkephalinergic pathways, most of which have connections with the central body. The complex patterns of immunoreactivity seen in terminals in the different parts of the central body, suggest an important role for the enkephalin-like peptides in the integration of multimodal sensory inputs. The physiological functions of the extended-enkephalin-like peptides in the brain of Calliphora is still unknown, but the anatomical evidence suggests they may have a role similar to that in mammals, where they are thought to control aspects of feeding behaviour.     

Formalism for the neural network of visual systems

A formalism to describe neural interrelations is developed on the exemplary case of the fly visual system. Absolute and relative indices are employed to identify the position of neural elements within the lattices of the visual ganglia. Illustrative applications as the projection of fly retinual cell axons into the lamina are discussed as well as the general feasibility of the formalism to other visual systems.     

LIFE IN ZERO MAGNETIC FIELD. IV. INVESTIGATION OF DEVELOPMENTAL EFFECTS ON FRUITFLY VISION

The fruitfly (Drosophila melanogaster) visual system was investigated electrophysiologically in vivo after exposure to a zero magnetic field (ZMF). Electroretinographic (ERG) recording of fly eye electrical activity was performed on adult insects raised from pupae maintained for 20 hr in zero magnetic field. A flickering excitation regime was applied to excite the visual system, since in this way, a quasistable hyperpolarization component of the electroretinogram can be obtained, containing information from the neural cells, which are the most sensitive to the action of external factors during early ontogenetic stages. Results of the investigation of two D. melanogaster populations, sample and control, were statistically compared.

We found a significant statistical increase of sensitivity in neural cells from the first optic ganglion in the fly population developed from pupae exposed to ZMF.     

The A5 antigen, a candidate for the neuronal recognition molecule, has homologies to complement components and coagulation factors

The A5 antigen is a neuronal cell surface protein of Xenopus presumed to be involved in the neuronal recognition between the optic nerve fibers and the visual centers. Analyses of cDNA clones revealed that the A5 antigen is a class I membrane protein containing two different internal repeats in the extracellular segment. The first repeat bears homology to domain III of complement components C1r and C1s, and the second repeat is homologous to the C1 and C2 domains of coagulation factors V and VIII. The mRNA for the A5 antigen was present in retinal ganglion cells and visual center neurons. Nonneuronal cells in the peripheral and central nervous systems did not express the mRNA for the A5 antigen.     

A model of the saccadic sensorimotor system of salamanders

A model of the saccadic system of salamanders on the basis of electrophysiological and anatomical results is presented. The model includes centers found to be significant for the guidance of saccades in these comparatively simple vertebrates. In particular, these are the optic tectum, the bulbar reticular formation and the motor system. The latter consists of two pairs of neck-muscles, an epaxial and a hypaxial one driven by their respective motoneurons. The model includes a visual, a sensori-motor, and a motor level. At the sensory level, the retinal coordinates are transferred to the optic tectum to establish an orthogonal map of visual angles. A secondary visual map of the ipsilateral eye with a pointsymmetrical organization exists in addition. The premotor system of the tectum was modelled according to an ensemble-coding principle. Thus, local activation of the visual map results in recruitment of an appropriate number of tectal premotor units. Simulation of the model reproduces correct metric properties of salamander saccades under varying stimulus presentations.     

Second-order ocellar neurons in the brain of the honeybee (Apis mellifera)

Summary Electrophoretic injection of Procion Yellow M-R4 into the ocellar tract of the worker bee has revealed the following:Two types of giant axon run from the lateral ocellus to the circumesophageal neuropile, where one branches ipsilaterally and the other contralaterally. A third type comes from the median ocellus and can be traced into the cervical connectives. The largest dendritic complex is in the circumesophageal neuropile; in addition, fiber endings have been demonstrated in the following areas: in the subretinal region, along the optic commissure, in the medulla interna, in the subesophageal ganglion and between the neurosecretory cells of the pars intercerebralis. — The giant fibers are enclosed in a glial sheath.Three types of cell body are described. One is associated with the glia; another, larger cell type comprises giant-axon somata. The third type of cell is small, and cannot yet be identified.Some of the histological results are discussed with respect to the possible function of the ocellus.     

Neurobiology of the scallop. II. structure of the parietovisceral ganglion lateral lobes in relation to afferent projections from the mantle eyes

The lateral lobes of the scallop parietovisceral ganglion have been examined morphologically with respect to their functional role as optic lobes. The gross morphology of the lateral lobe and projections of optic nerve fibers within it were investigated by 1) supravital methylene blue staining, and 2) autoradiography using tritiated proline injected intraocularly for incorporation and transport by the optic fibers. Ultrastruc‐turally, the lateral lobe was examined using standard electron microscopic techniques. The lateral lobe is composed of a cortical rind of cells, 8–15 μm in diameter at the ventral surface and 15–20 μm in diameter at the ventral surface, surrounding a central neuropil. The neuropil contains three distinct regions: 1) the glomerular neuropil, a series of densely staining spherical subunits associated with the eyes and pallial nerves, 2) the subcellular neuropil, a synaptic region adjacent to the ventral cell layer also having a visual function, and 3) the subglomerular neuropil, the remaining, rather unspecialized neuropil of the lateral lobe. Synaptic profiles with symmetrical membrane thickenings, a 32 nm synaptic cleft, and three types of vesicles are seen throughout the neuropil, although the density of synapses is greater in the glomerular region. Clear, dense core and neurosecretory vesicles are seen individually or as mixed populations in the presynaptic terminals. Autoradiographic experiments have revealed that optic fibers enter the lateral lobe and project directly to the subcellular neuropil where they synapse with cells located on the ventral surface of the lateral lobe cells. These cells in turn form the dense glomerular structures previously identified as visual association centers and send efferent fibers into the pallial nerves. The projection of optic fibers to the ventral surface of the lobe is consistent with previous electrophysiological recordings of visual activity at this site.     

Temporal resolution of colour vision in the honeybee

Summary Extracellular recordings have been made from ganglion cells of the lemon shark retina: ON, OFF and ON-OFF units were recorded. Spectral sensitivity measurements under darkadapted conditions reveal a _max of 519–522 nm. This may be due to two photoreceptor systems. A second class of ganglion cells was characterized as receiving input from a single 544 nm visual pigment system.