A light microscopic study of the axonal collaterals of the lumbar motoneurons in the spinal cord of the frog Rana ridibunda]

By using intracellular injection of horseradish peroxidase into the lumbar motoneurones of the isolated spinal cord of the frog Rana ridibunda the structure of axon collaterals was studied. It was shown that about 50% of the HRP-stained cells had mainly one axon collateral of the 1st order. The subsequent branching patterns of the collaterals showed considerable variations. The number of swellings in various collaterals was from 10 up 100. The mean diameter of swellings varied from 0.8 up 10.0 microns. It is believed that the axon collateral swellings from contacts on the dendrites of the nerve cells mainly. Apparent axosomatic contacts were revealed on the motoneurons and small nerve cells. As in the cat, collateral swellings were found on the dendrites of the parent motoneuron. Obtained morphological data the structure of motor axon collaterals in the frog are compared with those in the cat. Functional significance of the axon collateral in the frog is discussed.     

Vasopressinergic axon collaterals and axon terminals in the magnocellular neurosecretory nuclei of the rat hypothalamus

Axon collaterals emerging from the vasopressinergic neurons of the supraoptic (SON) and paraventricular (PVN) nuclei and recurving back towards their respective nuclei have been previously reported. Since such axon collaterals can play a role in the neuromodulation of SON and PVN, these nuclei have been further investigated immunohistochemically under the light and electron microscope. The PAP technique, using a commercial antibody, was employed. Vasopressin-positive axon collaterals were seen to recurve towards their nuclei of origin. In the latter, vasopressinergic intrinsic neurons were also observed. Under the electron microscope, axon terminals containing vasopressin-immunoreactive neurosecretory granules were noted. Such terminals presumably arise from the vasopressin-positive recurrent axon collaterals or from the intrinsic neurons for the purpose of neuromodulation within the SON and PVN.     

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.     

Recurrent axon collaterals of lumbar motor neurons in turtles

A combined morphophysiological study was made of connections between motoneurons on the superfused isolated lumbar spinal cord of Testudo horsfieldi. Postsynaptic potentials of motoneurons, followed by antidromic stimulations of ventral root filaments (VR-PSPs), were recorded intracellularly. Depolarizing VP-PSPs had short latencies (1.0-1.5 mc) and amplitudes in the range of 0.3-3.0 mV. At the constant stimulus intensity, the fluctuations of amplitudes were recorded. In some motoneurons, hyperpolarizing VP-PSRs with the latencies 2.5-3.0 mc were observed. A possible structural basis of VR-PSPs was studied by the horseradish peroxidase (HRP) method. After HRP application on thin ventral root filaments the retrograde staining of motoneurons revealed recurrent axon collaterals of labeled motoneurons. Three-dimensional computer reconstructions showed one to three collaterals given off by motoneuron axons. There were up to 19 points of branching in a single collateral. In some cases the full length of collateral trees reached 4.0 mm. The collateral branches had up to 72 "en passant" and terminal axon swellings. The swellings (presumed contacting boutons) were distributed in the ventral and intermedial gray matter and in the ventromedial while matter and revealed on motoneurons and inerneurons. These data suggest the participation of the motor axon collaterals in the motoneuron--motoneuron communication in the turtle spinal cord whereas only dendro-dendritic contacts had been discussed earlier.     

Synapses on axon collaterals of pyramidal cells are spaced at random intervals: a Golgi study in the mouse cerebral cortex

In this study we investigated the arrangement of synapses on local axon collaterals of Golgi-stained pyramidal neurons in the mouse cerebral cortex. As synaptic markers we considered axonal swellings visible at high magnification under the light microscope. Such axonal swellings coincide with synaptic boutons, as has been demonstrated in a number of combined light and electron microscopic studies. These studies also indicated that, in most cases, one bouton corresponds precisely to one synapse. Golgi-impregnated axonal trees of 20 neocortical pyramidal neurons were drawn with a camera lucida. Axonal swellings were marked on the drawings. Most swellings were ‘en passant’; occasionally, they were situated at the tip of short, spine-like processes. On axon collaterals, the average interval between swellings was 4.5 μm. On the axonal main stem, the swellings were always less densely packed than on the collaterals. Statistical analysis of the spatial distribution of the swellings did not reveal any special patterns. Instead, the arrangement of swellings on individual collaterals follows a Poisson distribution. Moreover, the same holds to a large extent for the entire collection of pyramidal cell collaterals. This suggests that a single Poisson process, characterized by only one rate parameter (number of synapses per unit length), describes most of the spatial distribution of synapses along pyramidal cell collaterals. These findings do not speak in favour of a pronounced target specificity of pyramidal neurons at the synaptic level. Instead, our results support a probabilistic model of cortical connectivity. Received: 6 June 1993/Accepted in revised form: 22 December 1993     

SEMA3A regulates developing sensory projections in the chicken spinal cord

The present study explores the role of SEMA3A (collapsin-1) in the temporal and spatial regulation of developing sensory projections in the chick spinal cord. During development, SEMA3A mRNA (SEMA3A) is first expressed throughout the spinal gray matter, but disappears from the dorsal region when small caliber (trkA(+)) sensory axon collaterals first grow into the dorsal horn. In explant cultures of spinal cord segments with attached sensory ganglia, the spatial extent of SEMA3A expression varied in different explants, but in each case the growth of trkA(+) sensory collaterals was largely excluded from areas of SEMA3A expression. To test if SEMA3A had a direct effect on sensory axon growth, we injected recombinant protein into the explants before placing them in culture. Increased levels of SEMA3A substantially reduced the ingrowth of trkA(+) axons, whereas trkC(+) axon collaterals were not affected. Consistent with the insensitivity of trkC(+) collaterals to SEMA3A, these collaterals did not express neuropilin-1, a receptor for SEMA3A. The inhibitory effects of SEMA3A on trkA(+) axons within the spinal cord suggests that the fall in SEMA3A expression in the dorsal horn may contribute to the initiation of growth of these axons into gray matter. In addition, the observation that trkA(+) axons frequently grew close to but rarely over areas of SEMA3A expression suggests that semaphorin may act principally as a short-range guidance cue within the spinal cord.     

Morphology of electrophysiologically identified baroreceptor afferents and second order neurones in the brainstem of the cat

Baroreceptor afferent fibres and second order baroreceptor neurones were identified by their discharge pattern and were intracellularly injected with horseradish peroxidase. Three afferent fibres and three second order neurones were reconstructed by camera lucida drawings from serial sections of the brainstem. The afferent fibres were classified as A delta-fibres and had terminal arborizations with synaptic boutons in the dorsomedial region of the nuclei of the solitary tract (TS). The afferent fibres had additional collaterals with a medial projection to the commissural nucleus and in a direction lateral to the TS. The terminals of these collaterals could not be demonstrated. The second order neurones were located in the same dorsomedial region as the synaptic boutons of the afferent fibres. Neurones were small and spindle-shaped with two primary dendrites: one dendrite projected cranially along the medial border of the TS, and the second one projected caudally and medially into the commissural nucleus. The unmyalinated axons of these neurones could be traced over a distance of 1 mm. In only one neurone could an axon collateral be detected. The axons projected dorsally around the TS in a ventrolateral direction beyond the boundaries of the nuclei of the TS. The axon collateral projected in the medial direction into the commissural nucleus. In no case were axon terminals demonstrated.     

Neurons and their interconnections in the frontal cortex of monkeys

It was shown by the Golgi and Golgi-Kopsch method that pyramidal cells of layers II–IV in the frontal cortex of the monkeyMacaca rhesus have numeruous, mainly recurrent axon collaterals by means of which they form vertical connections. Pyramidal cells with ascending axons are found. Axons of stellate basket neurons unite pyramidal cells in both horizontal (modules) and vertical (micromodules) directions; depending on the direction of the axon collaterals, two groups of stellate neurons can be distinguished. Groups of 14 to 16 pyramidal cells whose apical dendrites are connected into bundles were found. Axons of pyramidal cells in layers II–IV descend in the composition of the pyramidal tract and give off collaterals which run toward the bodies and dendrites of neighboring pyramidal cells, united into the same group, forming terminal and en passant junctions. Besides bundles, special kinds of "local" cell groups with U-shaped axons are found.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 15, No. 2, pp. 115–120, March–April, 1983.     

Neuroanatomical clues to peripheral locomotor control in small crustaceans (Artemia salina).

Brine shrimp (Artemia salina) were prepared for light and electron microscopy at several stages. Immersion-fixed, rapid Golgi impregnations demonstrated two distinct neuronal types in thoracic appendages of mature, freely swimming Artemia. Isolated motor neurons had large cell somas and thick, radiating dendrites at the body wall-limb junction. A long, elaborate axon extended into the limb. Groups of a second type of neuron with smaller somas and very thin, radiating processes occurred in the distal limb near presumably tactile bristles. Thick axons from motor neurons were traced to terminals associated with limb muscle. Both muscle and axon were best seen with Nomarski optics. Motor axons possessed elongate, irregularly shaped boutons en passant and morphologically variable boutons terminaux; the latter included huge endings with knobbed projectiles arising from thick collaterals, or smaller, round boutons from thin collaterals. In addition, a thick unidentified axon coursed longitudinally within the central body wall, sending short collaterals peripherally. The elaborate peripheral neurons described in this Golgi study may be anatomical correlates for the extraordinary coordination of mature brine shrimp. Because Artemia movements resemble those of leech and decapods, which have been studied extensively electrophysiologically, the possibility of similarly elaborate peripheral structures supplementing central control of locomotion in those invertebrates should be considered.     

The sensitivity of Renshaw cells to velocity of sinusoidal stretches of the triceps surae muscle.

1. The electrical activity of Renshaw cells monosynaptically excited by ventral root stimulation and disynaptically excited by electric stimulation of the group I afferents in the GS nerve has been recorded and their response to individual sinusoidal stretches of the deefferented GS muscle tested for different amplitudes and durations of the stimulus. 2. The experimental data indicate that the Rensahw cell responses are not only length dependent but also rate dependent. This finding indicates that the same Renshaw cells receive recurrent collaterals of both tonic and phasic motoneurons. 3. The observation that the discharge of Renshaw cells is particularly sensitive to the velocity of stretch suggests that the recurrent collaterals of large phasic motoneurons, which are recruited during high velocity stretches, exert a stronger excitatory action on Renshaw cells than do axon collaterals of the smaller tonic motoneurons, which are selectively stimulated during low velocity stretches.     

Morphology of lumbar-projecting lateral vestibulospinal neurons in the brainstem and cervical spinal cord in the squirrel monkey

The lateral vestibulospinal tract (LVST) is one of the major descending pathways controlling the extensor musculature of the body. To determine whether individual LVST neurons terminating in the lumbosacral spinal segments issue collaterals more rostrally to exert an influence of the cervical ventral horn intracellular recording and biocytin labeling techniques were used in the squirrel monkey. Only neurons monosynaptically related to the 8th nerve and antidromically identified to project below T12 were selected for study. The axon course through the brainstem and cervical spinal cord was examined in 37 LVST neurons. The average distance of recovered axon was 17.3 mm (4.5-31.7 mm). None could be antidromically activated from shocks applied to the rostral medial longitudinal fasciculus near the 3rd nuclei; and no collaterals were observed in the brainstem. Of the 37 neurons, only 1 axon issued a collateral to innervate the ventral horn, primarily in the region of the spinal accessory motoneurons; this single collateral provided a relatively minor input compared to that of LVST neurons terminating in the cervical cord. Thus, secondary, caudal-projecting LVST neurons represent a private, and mostly rapid, communication pathway between dorsal Deiters' nucleus and the motor circuits controlling the lower limbs and tail.     

Biochemical purification of a mammalian slit protein as a positive regulator of sensory axon elongation and branching

Many neurons in both vertebrates and invertebrates innervate multiple targets by sprouting secondary axon collaterals (or branches) from a primary axon shaft. To begin to identify molecular regulators of axon branch initiation or extension, we studied the growth of single sensory axons in an in vitro collagen assay system and identified an activity in extracts of embryonic spinal cord and of postnatal and adult brain that promotes the elongation and formation of extensive branches by these axons. Biochemical purification of the activity from calf brain extracts led to the identification of an amino-terminal fragment of Slit2 as the main active component and to the discovery of a distinct activity that potentiates its effects. These results indicate that Slit proteins may function as positive regulators of axon collateral formation during the establishment or remodeling of neural circuits.     

The demonstration of recurrent motor axon collaterals in the chick embryo by using horseradish peroxidase axonal transport]

Motoneurons were labelled by retrograde axonal transport of HRP applied to transected spinal nerves in 9-11-day chick embryos in the in vitro spinal cord preparation. Recurrent motor axon collaterals were revealed in 17 of 48 motor axons which could be followed in the edge regions of labelled motoneuronal pools. The results, coupled with author's earlier electrophysiological data, provide further evidence for the presence of the Renshaw inhibition in the avian spinal cord.     

Computation of action potential propagation and presynaptic bouton activation in terminal arborizations of different geometries.

Action potential propagation in axons with bifurcations involving short collaterals with synaptic boutons has been simulated using SPICE, a general purpose electrical circuit simulation program. The large electrical load of the boutons may lead to propagation failure at otherwise uncritical geometric ratios. Because the action potential gradually fails while approaching the branch point, the electrotonic spread of the failing action potential cannot depolarize the terminal boutons above an assumed threshold of 20 mV (Vrest = 0 mV) for the presynaptic calcium inflow, and therefore fails to evoke transmitter release even for boutons attached at short collaterals. For even shorter collaterals the terminal boutons can again be activated by the spread of passive current reflected at the sealed end of the bouton which increases the membrane potential above firing threshold. The action potential is then propagated in anterograde fashion into the main axon and may activate the terminal bouton on the other collateral. Differential activation of the synaptic boutons can be observed without repetitive activation of the main axon and with the assumption of uniform membrane properties. Axon enlargements above a critical size at branch points can increase the safety factor for propagation significantly and may serve a double function: they can act both as presynaptic boutons and as boosters, facilitating invasion of the action potential into the terminal arborizations. The architecture of the terminal arborizations has a profound effect on the activation pattern of synapses, suggesting that terminal arborizations not only distribute neural information to postsynaptic cells but may also be able to process neural information presynaptically.     

Ultrastructure within the Lateral Plexus of the Limulus Eye

The ultrastructure of the lateral plexus in the compound eye of Limulus is investigated by serial section technique. "Cores" of tissue containing the axons, lateral plexus, and neuropile associated with one sensory ommatidium show the following features: (a) collateral branches from retinular cells do not contribute to the lateral plexus proper, but do form retinular neuropile by contacting collaterals of a self-contained cluster of retinular axons; (b) collateral branches from eccentric cell axons always branch repeatedly upon leaving the parent axon, and compose the bulk of the lateral plexus; (c) the most distal collateral branches from an eccentric cell axon appear to form neuropile and synaptic contacts with each other, whereas more proximal branches form synaptic contacts with collaterals from eccentric cell axons of neighboring ommatidia. We conclude that the ribbon synapses and associated transmitter substance in eccentric cell collaterals must be inhibitory, and that two pathways for self-inhibition may exist. We suggest, as a working hypothesis for the structure of the lateral plexus, a branching pattern with depth that mirrors the horizontal spread of lateral inhibition measured physiologically.     

Activity regulates positive and negative neurotrophin-derived signals to determine axon competition

Developmental axon competition plays a key role in sculpting neural circuitry. Here, we have asked how activity and neurotrophins could interact to select one axon over another. Using compartmented cultures of sympathetic neurons, we show that, in the presence of NGF, local depolarization confers a competitive growth advantage on the depolarized axon collaterals and at the same time disadvantages the growth of unstimulated axons from the same and competing neurons. Depolarization mediates the competitive advantage by activating a CaMKII-MEK pathway, which converges to enhance local NGF-mediated downstream growth signals. Patterned electrical stimulation also acts via this pathway to enhance NGF-promoted axonal growth. In contrast, the competitive disadvantage is due to BDNF secreted from and acting on the unstimulated, competing axons through p75NTR. Thus, activity regulates both positive and negative neurotrophin-derived signaling cascades to confer a competitive growth advantage on one axon versus another, thereby providing a cellular mechanism for developmental axon selection.     

Ultrastructural alterations in the initial segments and in the recurrent collateral terminals of Purkinje cells following axotomy

Summary Transection of Purkinje cell axons in adult male rats made 1.5 mm or further from the cell body does not lead to the death of the neuron and results in compensatory structural alterations of the surviving axonal portions of the nerve cell. Near to, and at the emergence of recurrent collaterals of Purkinje cell axons, huge varicosities filled with filaments, granular material, lysosomes and mitochondria develop. Terminals of recurrent axon collaterals also exhibit different degrees of structural changes. Most striking of the morphological alterations is the regular presence of nematosomes in the hypertrophic axonal branches, especially in synaptic terminals. Since nematosomes were shown to contain RNA in other types of neurons, their presence in recurrent collaterals may indicate an enhanced synthetic activity in Purkinje axonal processes and endings after axotomy.     

Activation of locus coeruleus neurons by peripheral stimuli: modulation by a collateral inhibitory mechanism.

Noradrenergic neurons of the rat locus coeruleus (LC) respond to noxious stimuli or peripheral nerve stimulation with a burst of spikes followed by a period of suppressed activity. During this period of post-activation suppression, responses to additional stimuli were attenuated. After antidromic activation of the LC there was also a period of reduced responsivity, presumably mediated by inhibitory recurrent LC collaterals. The suppression of LC unit firing which follows nerve stimulation was reduced by piperoxane, an α-adrenergic antagonist which is known to block the norepinephrine-mediated autoinhibitory action of recurrent LC axon collaterals. The specificity of piperoxane in blocking norepinephrine was shown by the fact that it did not antagonize several other putative transmitters in the LC (i.e., GABA, glycine, and met-enkephalin). It is concluded that the post-activation reduction of LC neuronal responsivity may be mediated in part through noradrenergic autoinhibitory mechanisms within the LC.     

Morphological characteristics of lateral rectus motoneurones shown by intracellular injection of HRP.

The morphology of identified lateral rectus motoneurones is described after staining by intracellular iontophoresis of horseradish peroxidase. Soma vary in shape and size according to the number and orientation of primary dendrites. The basic pattern of arborisation shows short primary dendrites which branch close to the soma, forming a distal ramification extending over 600 to 1,200 micrometer from the soma. Distal dendrites extend into the ipsilateral medial vestibular nucleus, the reticular formation and amongst the fibres of the medial longitudinal fasciculus. This extension is greater than that previously seen in procion yellow and Golgi stained lateral rectus motoneurones. The axon originates from the perikarya or from the base of a primary dendrite. No axon collaterals have been observed.     

Interactions between cerebellar Purkinje cells and their associated astrocytes

Some neurons, including cerebellar Purkinje cells, are completely ensheathed by astrocytes. When granule cell neurons and functional glia were eliminated from newborn mouse cerebellar cultures by initial exposure to a DNA synthesis inhibitor, Purkinje cells lacked glial sheaths and there was a tremendous sprouting of Purkinje cell recurrent axon collaterals, terminals of which hyperinnervated Purkinje cell somata, including persistent somatic spines, and formed heterotypical synapses with Purkinje cell dendritic spines, sites usually occupied by parallel fiber (granule cell axon) terminals. Purkinje cells in such preparations failed to develop complex spikes when recorded from intracellularly, and their membrane input resistances were low, making them less sensitive to inhibitory input. If granule cells and oligodendrocytes were eliminated, but astrocytes were not compromised, sprouting of recurrent axon collaterals occurred and their terminals projected to Purkinje cell dendritic spines, but the Purkinje cells had astrocytic sheaths, their somata were not hyperinnervated, the somatic spines had disappeared, complex spike discharges predominated, and membrane input resistance was like that of Purkinje cells in untreated control cultures. When cerebellar cultures without granule cells and glia were transplanted with granule cells and/or glia from another source, a series of changes occurred that included stripping of excess Purkinje cell axosomatic synapses by astrocytic processes, reduction of heterotypical axospinous synapses in the presence of astrocytes, disappearance of Purkinje cell somatic spines with astrocytic ensheathment, and proliferation of Purkinje cell dendritic spines after the introduction of astrocytes. Dendritic spine proliferation was followed by formation of homotypical axospinous synapses when granule cells were present or persistence as unattached spines in the absence of granule cells. The results of these studies indicate that astrocytes regulate the numbers of Purkinje cell axosomatic and axospinous synapses, induce Purkinje cell dendritic spine proliferation, and promote the structural and functional maturation of Purkinje cells.