Neuronal nitric oxide synthase immunopositive neurons in cat claustrum—a light and electron microscopic study

Nitric oxide is a unique neurotransmitter, which participates in many physiological and pathological processes in the organism. Nevertheless there are little data about the neuronal Nitric Oxide Synthase immunoreactive (nNOS-ir) neurons and fibers in the dorsal claustrum (DC) of a cat. In this respect the aims of this study were: (1) to demonstrate nNOS-ir in the neurons and fibers of the DC; (2) to describe their light microscopic morphology and distribution; (3) to investigate and analyze the ultrastructure of the nNOS-ir neurons, fibers and synaptic terminals; (4) to verify whether the nNOS-ir neurons consist a specific subpopulation of claustral neurons; (5) to verify whether the nNOS-ir neurons have a specific pattern of organization throughout the DC. For demonstration of the nNOS-ir the Avidin-Biotin-Peroxidase Complex method was applied. Immunopositive for nNOS neurons and fibers were present in all parts of DC. On the light microscope level nNOS-ir neurons were different in shape and size. According to the latter they were divided into three groups-small (with diameter under 15 mum), medium-sized (with diameter from 16 to 20 mum) and large (with diameter over 21 mum). Some of nNOS-ir neurons were lightly-stained while others were darkly-stained. On the electron microscope level the immunoproduct was observed in neurons, dendrites and terminal boutons. Different types of nNOS-ir neurons differ according to their ultrastructural features. Three types of nNOS-ir synaptic boutons were found. As a conclusion we hope that the present study will contribute to a better understanding of the functioning of the DC in cat and that some of the data presented could be extrapolated to other mammals, including human.     

Neuronal nitric oxide synthase immunopositive neurons in cat vestibular complex: a light and electron microscopic study

Nitric oxide is a unique neurotransmitter, which participates in many physiological and pathological processes in the organism. Nevertheless, there are little data about the neuronal nitric oxide synthase immunoreactivity (nNOS-ir) in the vestibular complex of a cat. In this respect, the aims of this study were to: (1) demonstrate nNOS-ir in the neurons and fibers, from all major and accessory vestibular nuclei; (2) describe their light microscopic morphology and distribution; (3) investigate and analyze the ultrastructure of the NOS I-immunopositive neurons, fibers, and synaptic boutons. For demonstration of the nNOS-ir, the peroxidase–antiperoxidase–diaminobenzidin method was applied. Immunopositive for nNOS neurons and fibers were present in all major and accessory vestibular nuclei. On the light microscope level, the immunopositive neurons were different in shape and size. According to the latter, they were divided into four groups—small (with diameter less than 15 μm), medium-sized (with diameter from 15 to 30 μm), large type I (with diameter from 30 to 40 μm), and large type II (with diameter greater than 40 μm). On the electron microscope level, the immunoproduct was observed in neurons, dendrites, and terminal boutons. According to the ultrastructural features, the neurons were divided into three groups—small (with diameter less than 15 μm), medium-sized (with diameter from 15 to 30 μm), and large (with diameter greater than 30 μm). At least two types of nNOS-ir synaptic boutons were easily distinguished. As a conclusion, we hope that this study will contribute to a better understanding of the functioning of the vestibular complex in cat and that some of the data presented could be extrapolated to other mammals, including human.     

Slowly contracting muscles power the rapid jumping of planthopper insects (Hemiptera, Issidae)

The planthopper insect Issus produces one of the fastest and most powerful jumps of any insect. The jump is powered by large muscles that are found in its thorax and that, in other insects, contribute to both flying and walking movements. These muscles were therefore analysed by transmission electron microscopy to determine whether they have the properties of fast-acting muscle used in flying or those of more slowly acting muscle used in walking. The muscle fibres are arranged in a parallel bundle that inserts onto an umbrella-shaped tendon. The individual fibres have a diameter of about 70 μm and are subdivided into myofibrils a few micrometres in diameter. No variation in ultrastructure was observed in various fibres taken from different parts of the muscle. The sarcomeres are about 15 μm long and the A bands about 10 μm long. The Z lines are poorly aligned within a myofibril. Mitochondrial profiles are sparse and are close to the Z lines. Each thick filament is surrounded by 10–12 thin filaments and the registration of these arrays of filaments is irregular. Synaptic boutons from the two excitatory motor neurons to the muscle fibres are characterised by accumulations of ~60 translucent 40-nm-diameter vesicle profiles per section, corresponding to an estimated 220 vesicles, within a 0.5-μm hemisphere at a presynaptic density. All ultrastructural features conform to those of slow muscle and thus suggest that the muscle is capable of slow sustained contractions in keeping with its known actions during jumping. A fast and powerful movement is thus generated by a slow muscle.     

Axons of sacral preganglionic neurons in the cat: II. Axon collaterals

Axon collaterals were identified in 21 of 24 preganglionic neurons in the lateral band of the sacral parasympathetic nucleus of the cat. Following the intracellular injection of HRP or neurobiotin the axons from 20 of these neurons were followed and 53 primary axon collaterals were found to originate from unmyelinated segments and from nodes of Ranvier. Detailed mapping done in the five best labeled cells showed bilateral axon collaterals distributions up to 25,000 μm in length with 950 varicosities and unilateral distributions up to 12,561 μm with 491 varicosities. The axon collaterals appeared to be unmyelinated, which was confirmed at EM, and were small in diameter (average 0.3 μm). Varicosities were located mostly in laminae I, V, VII, VIII and X and in the lateral funiculi. Most varicosities were not in contact with visible structures but some were seen in close apposition to Nissl stained somata and proximal dendrites. Varicosities had average minor diameters of 1.3 μm and major diameters of 2.3 μm. Most were boutons en passant while 10–20% were boutons termineaux. EM revealed axodendritic and axoaxonic synapses formed by varicosities and by the axons between varicosities. It is estimated that the most extensive of these axon collaterals systems may contact over 200 spinal neurons in multiple locations. These data lead to the conclusion that sacral preganglionic neurons have multiple functions within the spinal cord in addition to serving their target organ. As most preganglionic neurons in this location innervate the urinary bladder, it is possible that bladder preganglionic neurons have multiple functions.     

Calcitonin Gene-Related Peptide (CGRP)-Positive Neurons and Fibers in the Cat Periaqueductal Grey Matter

The morphology and topographical distribution of neurons and terminals containing calcitonin gene-related peptide (CGRP) immunoreactivity in the cat periaqueductal grey (PAG) were studied using a rabbit antiserum raised against the C-terminal region of rat α-CGRP. In normal cats, numerous fibers, but rarely immunoreactive neurons, were observed in the PAG. CGRP-containing fibers showed bouton-like swellings along their length and expanded in terminal clusters of boutons. In many cases, CGRP-positive fibers were also observed in close association with small blood vessels. Immunoreactive fibers were particularly numerous at caudal PAG levels, mostly in its ventrolateral portion. In colchicine-treated cats, the pattern of CGRP-containing fibers was basically unchanged, despite a reduction of both the number of fibers and the intensity of fiber staining; in addition, numerous CGRP-positive neurons were found, mostly in the ventrolateral portion of the caudal PAG. These neurons were fusiform, spheroidal, and triangular in shape. The selective distribution of CGRP-positive elements in the PAG suggests a functional specialization of these neurons in the activation of pain-modulating mechanisms.     

Calcitonin gene-related peptide (CGRP)-positive neurons and fibers in the cat periaqueductal grey matter

The morphology and topographical distribution of neurons and terminals containing calcitonin gene-related peptide (CGRP) immunoreactivity in the cat periaqueductal grey (PAG) were studied using a rabbit antiserum raised against the C-terminal region of rat alpha-CGRP. In normal cats, numerous fibers, but rarely immunoreactive neurons, were observed in the PAG. CGRP-containing fibers showed bouton-like swellings along their length and expanded in terminal clusters of boutons. In many cases, CGRP-positive fibers were also observed in close association with small blood vessels. Immunoreactive fibers were particularly numerous at caudal PAG levels, mostly in its ventrolateral portion. In colchicine-treated cats, the pattern of CGRP-containing fibers was basically unchanged, despite a reduction of both the number of fibers and the intensity of fiber staining; in addition, numerous CGRP-positive neurons were found, mostly in the ventrolateral portion of the caudal PAG. These neurons were fusiform, spheroidal, and triangular in shape. The selective distribution of CGRP-positive elements in the PAG suggests a functional specialization of these neurons in the activation of pain-modulating mechanisms.     

Functional aspects of the relation between the claustrum and motor cortex in the cat

In order to study the relationships between the claustrum and motor cortex neurons both of area 4 and area 6 in the cat, an experiment was performed in which the effect of claustral stimulation on pyramidal tract neurons was investigated. Single shock electrical activation of the claustrum caused an inhibition of the spontaneous activity of the neurons, or an inhibition preceded by short activation, or no effect. These evidences lead to the conclusion that the claustrum exerts a role in movement organization.     

虫疫霉属新种和中国新记录

本文报道了虫疫霉属2个新种及1个中国新记录种。新种北虫疫霉(Eryniaborea Fan et Li sp.nov.)发生于西北及东北地区的丽蝇成虫体上,菜叶蜂虫疫霉(Eryniaathaliae Li et Fan sp.nov)发生于陕西杨陵的黄翅菜叶蜂幼虫;新记录种近藤虫疫霉(Erynia kondoiensis Milner)发生于福州的烟蚜虫体上。本文详细描述了新种的形态。     

Chance or design? Some specific considerations concerning synaptic boutons in cat visual cortex

To understand the rules by which axons lay down their synaptic boutons we analyzed the linear bouton distributions in 39 neurons (23 spiny, 13 smooth) and 3 thalamic axons, which were filled intracellularly with horseradish peroxidase (HRP) during in vivo experiments in cat area 17. The variation of the total number of boutons and the total axonal length was large (789–7912 boutons, 12–126 mm). The overall linear bouton density for smooth cells was higher than that of spiny cells and thalamic afferents (mean ± sd, 110 ± 21 and 78 ± 27 boutons per mm of axonal length). The distribution of boutons varied according to their location on the tree. Distal axon collaterals (first and second order segments in Horton-Strahler ordering) of smooth neurons had a 3.5 times higher, spiny cells and thalamic afferents a 2 times higher bouton density compared to the higher order (more proximal) segments. The distribution of interbouton intervals was positively skewed and similar for cells of the same type. In most cases a γ-distribution fitted well, but the distributions had a tendency to have a heavier tail. To a first approximation these bouton distributions are consistent with both diffuse and specific models of interneuronal connections. Quite simple rules can explain these distributions and the connections between the different classes of neurons.     

Connections of the second auditory cortical area with the medial geniculate body and the first auditory area

Extra — and intracellular unit responses in area AII to stimulation of geniculocortical fibers and of area AI were studied in cat immobilized with D-tubocurarine. In response to stimulation of geniculocortical fibers, antidromic mono-, di-, and polysynaptic spikes were generated by neurons in area AII. The number of antidromic responses in area AII was about half that found in area AI under the same conditions of stimulation. Most of the orthodromic responses were di- and polysynaptic. Intracellular responses also were recorded in the form of EPSPs, EPSP-IPSPs, and primary IPSPs. Stimulation of area AI evoked responses in the neurons of area AII with latent periods of 0.75–6.0, 6.1–16.0, 18.0–23.0, and 60–100 msec. Removal of the medial geniculate body led to a marked decrease in the number of responses with latent periods of 6.1–16.0 msec. Some neurons of area AII responded by spikes to stimulation of both the geniculocortical fibers and area AI. Comparison of the latent periods of responses to these two types of stimulation showed that impulses from area AI to area AII are directed both to input neurons for impulses from the medial geniculate body and to neurons at subsequent stages of the intracortical neuronal change. In response to stimulation of cortical area AI, disynaptic IPSPs appeared in many neurons of area AII. Only one IPSP with a latent period of 1.0 msec, regardable as monosynaptic, was recorded.     

Postnatal development of the corticothalamic projections from the visual association cortex to the lateralis posterior complex in the cat

The postnatal development of the corticothalamic projection from the lateral suprasylvian cortex (LS) to the lateral medialis-suprageniculate nucleus (LM-Sg) of the cat thalamus was assessed by means of the anterograde tracer biocytin. In the adult, two types of corticothalamic fibers were found: type I established a network of fine fibers present throughout the LM-Sg, it was characterized by a linear sequence of small (less than 0.5 microm in diameter), single terminal boutons making contact mainly with thin dendrites and/or dendritic spines. Type II, found less frequently, gave off short, side branches near axon terminals and formed clusters of 5-10 large terminal boutons (0.5-1.5 microm in diameter), making contact predominately with medium-sized dendrites and/or vesicle-containing profiles, forming a synaptic glomerulus. At birth (P0), anterogradely-labeled fibers were found in the LM-Sg as in adults. In the early postnatal period (until P6) as well as around the time of eye-opening (P7-P10) to P21, neonatal fibers were largely unbranched many of them having axons tipped with growth cones. Axon terminals containing synaptic vesicles were rarely observed but when present these exhibited considerable variation in their morphological appearance of synapses. Thus, it was not possible to categorize them into the two types of axons which characterize the adult. After P25, terminal swellings bearing a close resemblance to those of type II fibers begin to appear. In this way, the main two corticothalamic fiber types could be identified. These findings demonstrate that significant postnatal changes occur in the synaptology of corticothalamic fibers in the LM-Sg, particularly with the maturation of type II fibers.     

Ultrastructural localization of nitric oxide synthase immunoreactivity in the cat ventrobasal complex

This study describes the ultrastructural localization of nitric oxide synthase (NOS) immunoreactivity in the cat ventrobasal complex. NOS immunoreactivity was found in the cell bodies and dendrites of local circuit neurons and in vesicle-containing profiles. The vesicle-containing profiles could be divided into two classes, those of dendritic origin (presynaptic dendrite boutons) and those of axonal origin. The NOS labelled axon terminals varied in size and packing density and were principally located in the extra-glomerular neuropil. These boutons presented a range of morphologies and it was not possible to determine the probable source based on morphological criteria. The NOS immunoreactive presynaptic dendrite boutons were found both within and outside glomeruli and established both pre- and post-synaptic relationships with other elements. Post-embedding GABA immunocytochemistry showed that some NOS immunoreactive axonal boutons and presynaptic dendrites were also immunopositive for GABA. This finding suggests that some of the NOS labelled axonal boutons are of local circuit neuron origin. These results suggest that local circuit neurons in the cat ventrobasal complex might be involved in specific, short range interactions using GABA and longer, more global interactions using nitric oxide.     

Ipsilateral,ventral corticospinal tract of the adult rat: Ultrastructure,myelination and synaptic connections

The corticospinal tract (CST) of the rat is a widely used model system in developmental, physiological, and regeneration studies. The CST of the rat consists of a main tract, that runs in the dorsomedial funiculus and several minor components. We have shown earlier that one of the minor components, the ipsilateral, ventral CST, projects all the way down the spinal cord in the adult rat and single fibers form large terminal arbors in their spinal target areas. Here we investigated its ultrastructure and compared it to that of CST fibers of the main tract. By the use of anterograde axonal tracing with biotin dextran-amine (BDA) and pre-embedding avidin-peroxidase histochemistry we investigated axon diameters and myelination using electron microscopy. Ipsilateral, ventral CST fibers were found to run in the ventral funiculus close to the midline. They were intermingled with heavily myelinated large diameter axons, presumably reticulospinal, vestibulospinal, or tectospinal fibers. Ipsilateral, ventral CST fibers were of small diameter (0.68 μm, ±0.04) and about [frac34] of them were moderately myelinated (9.64 ± 0.7 layers of myelin). Co-localization of a rhodamine-dextrane anterograde tracer with the presynaptic marker synaptophysin using confocal microscopy and electron microscopy revealed varicosities on terminal arborisations to be presynaptic boutons and clearly demonstrated contacts to neurons in intermediate laminae of the spinal cord at lumbar spinal levels. This study extends our earlier work indicating that the ipsilateral, ventral CST component of the adult rat is a morphologically complete CST component and may perform similar functions to the main CST component.     

Quantitative investigations of spinal motoneurons and their synaptic structures in a teleost: A morphometrical analysis with special reference to axosomatic synapses

The ultrastructural and morphometrical synaptology of the spinal motoneurons in Carassius auratus (goldfish) was analyzed based on profiles of 23 photomontages of large motoneurons and 25 putative small motoneurons with a semiautomatic digitizing system connected with a computer. In the 23 large motoneurons (mean circumference, 142.45 ± 39.76 μm) the total linear perikaryal circumference was 3,276.28 μm, of which 1,548.9 μm (46.1 ± 13.9%) was covered by terminal boutons. In contrast, a total linear perikaryal circumference of 1,375.24 μm (55.01 ± 14.34 μm) of the 25 putative small motoneurons was covered with terminal boutons only occupying a length of 287.45 μm (19.8 ± 11.9%). There were a total of 1,045 boutons on the large motoneurons and 204 on the small ones. The distribution of S- and F-type boutons may reflect excitatory and inhibitory synapses. The relative number of S-type boutons (58%) was larger than that of F-type boutons (42%) in the large neurons and showed similar values (S-type, 57%; F type, 43%) in the small ones. This is in contrast to mammalian spinal motoneurons in which F-type boutons are more prevalent than the S-type. The total numbers of the axosomatic boutons in large and small neurons were estimated, based on geometrical assumptions and found to differ substantially (840 vs. 59). This indicates large quantitative differences in the total number of synaptic inputs with the large motoneurons having a greater more axo-somatic bouton density. No large M- and C-type boutons occur on the spinal motoneurons of goldfish, suggesting a synaptic organization which is simple compared to that of terrestrial vertebrates. © 1993 Wiley-Liss, Inc.     

蚜虫的病原真菌新种——安徽虫疫霉

1984年初冬在安徽长江南北大面积蔬菜的桃蚜种群中发生真菌流行病。病原鉴定为虫霉目新种安徽虫疫霉(Erynia anhuiensis Li sp.nov)。分生孢子梗二歧分枝;初生分生孢子单核,双囊壁,长椭圆形、长卵形或倒拟卵形,前二者大小为17.1—33.3×5.9—12.9μm(平均24.7×8.3),长径比2.0—5.4(平均3.0),后者12.6—30.8×8.1—16.5μm(平均22.7×11.6),长径比1.4—2.5(平均2.0);有囊状体及假根,假根有固着器。外休眠孢子球形,光滑,透明,直径22.1—31.9μm(平均26.6)     

The neural basis of tactile texture perception

Running our fingers across a textured surface gives rise to two types of skin deformations, each transduced by different tactile nerve fibers. Coarse features produce large-scale skin deformations whose spatial configuration is reflected in the spatial pattern of activation of some tactile fibers. Scanning a finely textured surface elicits vibrations in the skin, which in turn evoked temporally patterned responses in other fibers. These two neural codes—spatial and temporal—drive a spectrum of neural response properties in somatosensory cortex: At one extreme, neurons are sensitive to spatial patterns and encode coarse features; at the other extreme, neurons are sensitive to vibrations and encode fine features. While the texture responses of nerve fibers are dependent on scanning speed, those of cortical neurons are less so, giving rise to a speed invariant texture percept. Neurons in high-level somatosensory cortices combine information about texture with information about task variables.     

Fine structure of the dorsal ocellus of the worker honeybee

The three dorsal ocelli of worker honeybees have been studied by light and electron microscopy. Each ocellus has a single flattened spheroidal lens and about 800 elongated retinular cells. Retinular cells are paired and form a two-part plate-like rhabdom between their distal processes. Each rhabdomere comprises parallel microvilli projecting laterally from the apposed retinular cells. Primary receptor cell axons synapse within the ocellus with ocellar nerve fibers of two different calibers. Each ocellus has eight thick fibers ca 10 m?m in diameter and several thinner ones less than 3 m?m in diameter. Fine structural evidence suggests that retinular axons end presynaptically on both types of ocellar nerve fibers. Since all retinular cells apparently synapse repeatedly with the thick fibers this involves a convergence of about 100:1. Thick fibers always terminate postsynaptically within the ocellus while thin fibers terminate presynaptically on other thin fibers, thick fibers or retinular axons. Structural evidence for synaptic polarization indicates that retinular cells and thick fibers are afferent, thin fibers efferent. Thus complex processing of the ocellar visual input can occur before the secondary neurons of the three ocelli converge to form the single short ocellar nerve which runs to the posterior forebrain.     

Three-dimensional microanatomy of perineuronal proteoglycan nets enveloping motor neurons in the rat spinal cord

Summary. Spinal motor neurons possess reticular coats of extracellular matrix proteoglycans on their somata and proximal dendrites. In order to define the anatomical background of the network, spatial relationships of the perineuronal proteoglycans with synaptic boutons and astrocyte processes were analyzed in rat motor neurons by TEM after histochemical detection of the substances with cationic iron colloid, and by SEM after exposure of the cytoarchitecture with NaOH maceration. Narrow intercellular channels filled with proteoglycan were found to extend along the surface of the neurons to form a homogeneous network of a mesh size of about 1 µm. The system of perineuronal channels consisted of two parts: a primary intervaricose net which meandered among synaptic boutons on the surface of the motor neuron, and secondary subvaricose nets which irrigated interfaces between larger boutons and the neuron. No elements in the perineuronal cytoarchitecture coincided with the meshwork of proteoglycan, indicating the involvement of postsynaptic factors in the distribution of the substance. Thin astrocyte processes surrounding the neurons formed a distinct network with heterogeneous meshes corresponding to boutons of various sizes. The perineuronal glial nets extended their surface area in contact with the intervaricose nets of proteoglycan by complex cellular interdigitations. The subvaricose nets of proteoglycan compartmentalized multiple synapses on large boutons, suggesting an involvement in the division of the synapses during development.