The projection of the lateral geniculate nucleus to area 17 of the rat cerebral cortex. I. General description.

Lesions were made in the lateral geniculate nucleus of the rat and the consequent degeneration in area 17 of the cerebral cortex was studied by light and electron microscopy. These lesions produced prominent degeneration of axon terminals in layer IV extending into layer III and a much lesser amount in layers I and VI. The darkened degenerating axon terminals forming asymmetric synaptic junctions and were frequently surrounded by hypertrophied astrocytic processes. These terminals appeared to be disposed randomly, forming no discernible patterns. In layer IV 83% of the synapsing, degenerating terminals formed junctions with dendritic spines, 15% with dendritic shafts, and 2% with neuronal perikarya. The dendritic shafts and neuronal perikarya appeared to belong to spine-free stellate cells. The dendrites giving rise to the spines receiving degenerating axon terminals could not be identified, for most of the spines appeared as isolated profiles that could not be traced back to their dendritic shafts. One example of a degenerating axon terminal synapsing with an axon initial segment was encountered. Small, degenerating myelinated axons were prevalent in layers VI, V and IV, but were only infrequent in the supragranular layers. These results are compared with those obtained in other studies of thalamocortical projections.     

An ultrastructural study of nerve terminal degeneration in muscle spindles of the tenuissimus muscle of the cat

Summary Muscle spindles in the tenuissimus muscle of the cat were studied between 12 and 168 h after cutting or freezing the nerve to this muscle. Degenerative changes in sensory and motor nerve terminals on intrafusal muscle fibres were observed using the electron microscope. Comparisons were made with spindles from unoperated or sham-operated cats.The earliest degenerative changes were seen in sensory and motor terminals at 20–24 h after the lesion. No nerve endings were seen by 114 h after denervation. The most consistent initial signs of degeneration were: (1) the presence of abnormal mitochondria and dense bodies in sensory terminals, and (2) a decrease in the number and clumping of synaptic vesicles combined with an increase in glycogen and neurofilaments in motor endings. Intrafusal fibres participate in the removal of degenerating sensory endings. Schwann cells phagocytose degenerating motor terminals. The disappearance of nerve terminals precedes the complete degeneration of preterminal myelinated fibres within the muscle spindle.     

皮质—脑桥核—小脑通路的HRP结合溃变电镜法研究

目的：观察大鼠脑桥核内皮质纤维终末的溃疡变型及其与脑桥核小脑投射神经元的突触联系方式,方法：采用HRP逆行标记结合溃变电镜技术。结果：（1）皮质纤维终末出现电子致密和微丝增生两种溃变类型。以电子致密型为主。后者终末又有两种不同形态,即含圆形清亮型小泡和多形清亮型小泡者,以圆形清亮型小泡终末占优势。（2）皮质纤维终末与脑桥核小脑投射神经元形成轴－树和少量轴－体突触,部分溃变终末与HRP标记的投射神经元形成单突触联系,结论：皮质纤维与脑桥核小脑投射神经元间存在的单突触联系构成了皮持－脑桥核－小脑通路。     

Thalamic inputs to identified commissural neurons in the monkey somatic sensory cortex

Summary Commissurally projecting neurons were identified in the monkey first somatic sensory area (SI) by the retrograde axonal transport of horseradish peroxidase (HRP) injected into the contralateral cortex. Neurons identified in this way have large pyramidal somata primarily in layer IIIB of the SI area. Their basal dendrites lie within the terminal plexus of thalamocortical afferents.Electron microscopy was used to examine the synaptic relations of the labelled commissural cells, in particular to determine whether they receive monosynaptic thalamic connections. To do this, retrogradely labelled commissural cells and Golgi-impregnated large pyramidal neurons from layer IIIB were examined ultrastructurally in material in which thalamocortical terminals were degenerating due to a prior lesion of the thalamus. In a significant number of cases degenerating terminals were found to make synapses on the spines or shafts of labelled dendrites.Injections of HRP into SI or into the white matter adjacent to the corpus callosum labelled callosal axons and terminals in the opposite SI. These axons terminated mainly near the somata of the layer IIIB pyramidal cells. Some of their terminals were found to synapse with dendrites receiving synaptic contacts from thalamocortical axon terminals.     

The action of capsaicin on primary afferent central terminals in the superficial dorsal horn of newborn mice

Capsaicin was injected subcutaneously (50 mg/kg) into 10 mice on days 2 or 3 after birth, and 12 h, 3 and 5 days later the distribution and structure of degenerated primary afferent central axons or terminals (C-terminals) in the lumbar spinal dorsal horn were examined by electron microscopy. Degenerated terminal axons with dense or lamellar bodies or higher electron density were conspicuous 12 h after treatment with capsaicin. Severely degenerated unmyelinated axons, including dense or lamellar bodies engulfed by microglial cells, were numerous in the most superficial (marginal) layer, but rarely seen in the substantia gelatinosa. Two types of primary afferent central terminals in the substantia gelatinosa showed various extents of degeneration: small dark C-terminals (CI-terminals) with densely packed agranular synaptic vesicles, and large light ones (CII-terminals) with less dense agranular synaptic vesicles and a few granular synaptic vesicles. Thus, many central axon terminals of dorsal root ganglion (DRG) neurons that are sensitive to capsaicin enter the marginal layer and substantia gelatinosa. Degenerated primary afferent central axons or terminals markedly decreased in the superficial dorsal horn 3 and 5 days after capsaicin treatment, still, there were many degenerating DRG neurons at this time as shown by our previous study. Previously we also reported that fewer slightly degenerating unmyelinated dorsal root axons and small DRG neurons appear at 12 h and larger DRG neurons degenerate later than smaller ones after treatment with capsaicin. As a result, the discovery of many severely degenerated terminal axons in the superficial dorsal horn soon after treatment supports the idea that capsaicin first acts on the central terminals and that this is followed by damage to larger DRG neurons.     

Ultrastructural studies of normal and degenerating mouse neuromuscular junctions

Summary A quantitative study of the ultrastructural changes occurring at degenerating motor axon terminals of the mouse hemidiaphragm in the first 26 h following unilateral phrenicotomy has been made. Several ultrastructural characteristics of axon terminals from normal diaphragms and phrenicotomized and control hemidiaphragms of phrenicotomized preparations were analyzed. Considerable swelling and disruption of mitochondria occurred in terminals of control hemidiaphragms at 3, 6 and 9 h post-phrenicotomy after which no more damage than that seen in normal terminals after fixation for electron microscopy was observed. At terminals of the phrenicotomized hemidiaphragm, much mitochondrial damage was observed from 3 h post-phrenicotomy onwards. In phrenicotomized hemidiaphragms all terminals had completely degenerated by 26 h post-phrenicotomy. Reduced synaptic vesicle population densities occurred during degeneration. At many axon terminals on phrenicotomized hemidiaphragms the population densities of synaptic vesicles were reduced compared with controls and vesicle aggregates were noted in many engulfed or partially engulfed nerve terminals.These results are discussed with respect to the vesicle hypothesis for nerve-muscle transmission. The mechanisms underlying Schwann cell hyperactivity are also considered.     

Morphological aspects of the elimination of polyneuronal innervation of skeletal muscle fibres in newborn rats

Summary The ultrastructure of neuromuscular junctions of rat soleus muscles 1–40 days postnatally was examined for possible morphological correlates of the transient polyneuronal innervation which is present in newborn rats.Several vesicle-laden profiles of terminal axons are seen to contact each muscle fibre up to 8 days postnatally. Axon terminals often lie close together, without Schwann cell intervention. Between days 8 and 16 the number of profiles of terminals on each muscle fibre is reduced, and both Schwann cells and ridge-like extensions of muscle fibre cytoplasm intervene between and separate axon terminals.No signs of degenerating intramuscular axons or axon terminals could be found. It is suggested that the redundant terminals are eliminated by retraction into the parent axons. This process is apparently accomplished without any morphological signs of degeneration.     

The electron microscopic localization of methionine-enkephalin within the superficial layers (I and II) of the spinal cord

The synaptic relationships of methionine-enkephalin containing axon terminals within layers I and II of the rat spinal cord have been investigated using immunocytochemical techniques. Labelled terminals contained large numbers of spherical synaptic vesicles and formed synaptic contacts with dendritic shafts and spines and to a lesser extent with cell bodies within the superficial layers of the dorsal horn. A large number of labelled terminals were seen in apposition to profiles containing pleomorphic vesicles, particularly within layer I and outer layer II. Following rhizotomy, degenerating primary afferent axon terminals were found throughout layers I and II but only in one case was a synaptic relationship with a labelled terminal observed.Thus we were unable to find a morphological correlate of the reported effects of opiates on sensory axons and terminals.     

Ultrastructural organization of the interstitial subnucleus of the nucleus of the tractus solitarius in the cat: Identification of vagal afferents

Summary This electron microscopic study, based on serial section analysis, describes the synaptic organization of the interstitial subnucleus of the nucleus of the solitary tract and identifies the terminals of the vagal primary afferents utilizing degeneration and HRP transport. The interstitial subnucleus contains sparsely scattered cell bodies, numerous dendrites and axon terminals, and bundles of unmyelinated and myelinated axons. The cell bodies which are small in diameter have an organelle poor cytoplasm and a large invaginated nucleus.Axon terminals can be classified into two main types according to their vesicular shape. The first type contains clear, round vesicles and can be further subdivided into two subgroups on the basis of their morphology and the size of their vesicles. In the first subgroup the terminals are small, contain a few mitochondria and their vesicles are densely packed with an homogeneous size. In the second subgroup the terminals which vary from small to large, contain many mitochondria and contain round vesicles which are heterogeneous in size. The second main terminal type consists of axon terminals containing pleomorphic vesicles which are associated with asymmetrical or symmetrical synaptic contacts on dendrites. Axo-axonic contacts are present in the interstitial subnucleus. In general, the presynaptic axon terminals contain pleomorphic vesicles and the postsynaptic elements contain round vesicles of varying size. In some dendrites, identified by the presence of ribosomes, groups of round and/or pleomorphic vesicles are found associated with synaptic contacts. These dendrites are presynaptic to conventional dendrites and postsynaptic to axon terminals. After removal of the nodose ganglion, degenerative alterations are seen only at the caudal and middle levels of the interstitial subnucleus. Degeneration occurs in a few myelinated axons and in axon terminals which usually contain a mixture of small and larger round, clear vesicles. After HRP injection into the vagus nerve, the HRP reaction product is visible in axon terminals filled with clear, round vesicles which are heterogeneous in size. The labelled axon terminals establish single or multiple synaptic contacts.This study demonstrates that terminals of vagal primary afferents consist principally of terminals of the second subgroup. The morphology of these terminals are compared to primary afferents in the brainstem and spinal cord.     

The use of ibotenic acid lesions for light and electron microscopic study of anterograde degeneration in the visual pathway of the cat

Ibotenic acid was injected in the lateral geniculate nucleus of cats to investigate the suitability of the technique in studies involving anterograde degeneration in the thalamo-cortical pathway when it is important not to damage fibres of passage at the lesion site. Small injections cause localized degeneration of neuronal somata in the lateral geniculate nucleus, but axons passing through the injected zone remain intact. Degeneration can be localized in visual cortex by light microscopic silver techniques and by electron microscopy. The appearance, density and distribution of degenerating cortical axon terminals is similar to what is found after thalamic electrolytic lesions.     

Ultrastructure of vestibular commissural neurons related to velocity storage in the monkey.

The angular vestibulo-ocular reflex maintains gaze during head movements. It is thought to be mediated by two components: direct and velocity storage pathways. The direct angular vestibulo-ocular reflex is conveyed by a three neuron chain from the labyrinth to the ocular motoneurons. The indirect pathway involves a more complex neural network that utilizes a portion of the vestibular commissure. The purpose of the present study was to identify the ultrastructural characteristics of commissural neurons in the medial vestibular nucleus that are related to the velocity storage component of the angular vestibulo-ocular reflex. Ultrastructural studies of degenerating medial vestibular nucleus neurons were conducted in monkeys following midline section of rostral medullary commissural fibers with subsequent behavioral testing. After this lesion, oculomotor and vestibular functions attributable to velocity storage were abolished, whereas the direct angular vestibulo-ocular reflex pathway remained intact. Since this damage was functionally discrete, degenerating neurons were interpreted as potential participants in the velocity storage network. Ultrastructural observations indicate that commissural neurons related to velocity storage are small and medium sized cells having large nuclei with deep indentations and relatively little cytoplasm, which are located in the lateral crescents of rostral medial vestibular nucleus. The morphology of degenerating dendritic profiles varied. Some contained numerous round or tubular mitochondria in a pale cytoplasmic matrix with few other organelles, while others had few mitochondria but many cisterns and vacuoles in dense granular cytoplasm. The commissural nature of these cells was further suggested by the presence of two different types of degenerating axon terminals in the rostral medial vestibular nucleus: those with a moderate density of large spherical synaptic vesicles, and those with pleomorphic, primarily ellipsoid synaptic vesicles. The recognition of two types of degenerating terminals further supports our interpretation that at least two morphological types of commissural neurons participate in the velocity storage network. The degenerating boutons formed contacts with a variety of postsynaptic partners. In particular, synapses were observed between degenerating boutons and non-degenerating dendrites, and between intact terminals and degenerating dendrites. However, degenerating pre- and postsynaptic elements were rarely observed in direct contact, suggesting that additional neurons are interposed in the indirect pathway commissural system. On the basis of these ultrastructural observations, it is concluded that vestibular commissural neurons involved in the mediation of velocity storage have distinguishing ultrastructural features and synaptology, that are different from those of direct pathway neurons.     

The ultrastructure of GABA-immunoreactive vestibular commissural neurons related to velocity storage in the monkey.

The purpose of the present study was to visualize the synaptic interactions of GABAergic neurons involved in the mediation of velocity storage. In the previous report, ultrastructural studies of degenerating neurons were conducted following midline section of rostral medullary commissural fibers with subsequent behavioral testing. The midline lesion caused functionally discrete damage to the velocity storage component, but not to the direct pathway, of the angular vestibulo-ocular reflex, and the degenerating neurons were interpreted as potential participants in the velocity storage network. We concluded that at least some of the commissural axons mediating velocity storage originate from clusters of neurons in the lateral crescents of the rostral medial vestibular nucleus. In the present report, immunocytochemical evidence is presented that many vestibular commissural neurons, putatively involved in mediating velocity storage, are GABAergic. These cells have large nuclei, small round or narrow tubular mitochondria, occasional cisterns and vacuoles, but few other organelles. Their axons are thinly-myelinated, and terminate in boutons containing mitochondria of similar ultrastructural appearance and a moderate density of round/pleomorphic synaptic vesicles. Such terminals often form axoaxonic synapses, and less frequently axodendritic contacts, with non-GABAergic elements. On the basis of the present results, we conclude that a portion of the commissural neurons of the velocity storage pathway is GABAergic. The observation of GABAergic axoaxonic synapses in this pathway is interpreted as a structural basis for presynaptic inhibition of medial vestibular nucleus circuits by velocity storage-related commissural neurons. Conversely, substantial ultrastructural evidence for postsynaptic inhibition of non-GABAergic commissural cells argues for a dual role for GABAergic terminals mediating velocity storage: presynaptic inhibition of non-GABAergic vestibular cells by GABAergic velocity storage commissural axons, and postsynaptic inhibition of non-GABAergic velocity storage cells by GABAergic axons. Both pre- and postsynaptic inhibitory arrangements could provide the morphologic basis for disinhibitory activation of the velocity storage network within local neuronal circuits.     

Fine structural study of the spinal cord and spinal ganglia in mice afflicted with a hereditary sensory neuropathy, dystonia musculorum

Dystonia musculorum in mice is a hereditary autosomal recessive disorder, characterized by a progressive neuromuscular incoordination. This paper describes the ultrastructural changes in the spinal cord and compares and correlates the results with changes in the spinal ganglia in dystonic mice. Ganglion cells exhibited various stages of degeneration and pyknosis. The dorsal roots of the spinal nerves showed severe degeneration and loss of myelinated fibres accompanied by fibrosis, whilst the ventral roots appeared normal. Nerve cells within the dorsal and intermediate grey matter (laminae I to VII) of the spinal cord showed chromatolysis, atrophy, and necrosis. Boutons exhibited glycogen accumulation or an increase in their electron density. Axonal changes consisted of focal swellings, marked accumulation of neurofilaments, membranous and dense bodies, and disintegration of axoplasm. Myelin sheath degeneration of Wallerian type and degenerating axons were prominent in the dorsal, lateral and ventral white columns of the spinal cord. Glial reactions in the spinal cord were limited to mild hypertrophy and hyperplasia of astrocytic processes. The process of phagocytic activity was not intense in spite of the presence of an abundance of degenerating myelin and cell debris. This study showed that the ultrastructural changes in the spinal cord are more severe than those seen with routine light microscopy. The detection of definite neuronal degeneration of the dorsal root ganglia and spinal cord suggests that the defect apparently operates at the level of cell bodies, as well as axons, of the primary and second order sensory neurons.     

Permanence of postsynaptic specializations in the frog sympathetic ganglion cells after denervation

Summary The junctional complex of the axosomatic synapses in the frog sympathetic ganglion is formed by active zones and attachment plates. 16% of the active zones present a dense band or subsynaptic formation on the postsynaptic side. Seven days after the preganglionic fibers have been cut, most of the axon terminals in the ganglion undergo degeneration. The junctional complex is broken by glial cytoplasm, which separates the axon terminals from the neuronal perikaryon. Two distinct morphological types of axonal degeneration are found at this stage: 1. dark and shrunken boutons with a honeycomb appearance, and 2. clear and swollen boutons. These two morphological varieties are interpreted as different aspects of the same degenerative process of the spiral apparatus. Ten days after transection of the preganglionic fibers, most of the degenerating axon terminals have disappeared, and only dark bodies, remnants of such endings, are seen in the glial cytoplasm. Twelve days after the experimental lesion, almost all the axon terminals have disappeared. In all three stages of survival the subsynaptic structures, postsynaptic differentiation and subsynaptic formation, remain unchanged. It is suggested that these structures are not intimately related to the functional integrity of the axon terminals.To the memory of Prof. Fernando de Castro     

Gracile nucleus of streptozotocin-induced diabetic rats

Summary This study reports ultrastructural changes in the gracile nucleus of male Wistar rats after streptozotocin-induced diabetes. During the acute phase (3–7 days) degenerating electron-dense dendrites and axon terminals were dispersed in the neuropil. Degenerating dendrites were characterized by an electron-dense cytoplasm, swollen mitochondria, dilated endoplasmic reticulum and scattered ribosomes. Degenerating axon terminals were characterized by an electron-dense cytoplasm and clustering of small spherical agranular vesicles. Degenerating axon terminals may form part of a synaptic glomerulus with a central electron-dense dendrite, or they may form the central element of a synaptic glomerulus. These degenerating profiles were absent in the gracile nucleus of the 3 and 7 days insulin-treated post-streptozotocin rats. Macrophages were present in the neuropil and were in the process of engulfing neuronal elements. During the medium phase (1–6 months), most of the degenerating dendrites and axon terminals had been engulfed or removed by macrophages. During the late phase (9–12 months) a second wave of degeneration occurred in the gracile nucleus, similar to the acute phase. During the medium and late phases, dystrophic axonal profiles were also significantly increased in the rats after streptozotocin treatment.It is concluded that the ultrastructural changes observed in the gracile nucleus in the present study were the result of streptozotocin-induced diabetes rather than a toxic effect of streptozotocin, even in the acute phase.     

Traumatic degeneration of transected myelinated fibers of the mouse sciatic nerve.

Traumatic degeneration of myelinated fibers was studied by electron microscopy over 5 days following transection of mouse sciatic nerve. Special attention was paid to the mechanism which separates the degenerating part, while preserving the viable part of the axon. Immediately after transection, the opened end of the proximal stump revealed extensive subcellular changes including the disorganization of neurofilaments, and disruption of mitochondria and axonal endoplasmic reticulum (SER). Subsequently, vesicles of round and tubular profiles filled up the whole area of the stump end, and proximal to it appeared a neurofilament-predominant area characterized by randomly oriented neurofilaments and normally appearing mitochondria and SER. Characteristic membranous demarcations occurred in early periods at the border between the vesicle accumulation and the neurofilament-predominant areas, and later also within these areas. The demarcation membranes formed both by invagination of the surface plasma membrane and, probably, by fusion of the large vesicles. These became prominent with time, dividing the axoplasm into compartments of varying sizes, which gradually underwent degeneration and were liberated from the parent axon. Occurrence of autophagic vacuoles was characteristic of the degenerating portions of the parent axon. Thus, by the function of demarcation membranes, the parent axon to be preserved could remain membrane-bound, while the degenerating parts were shed off.     

Ultrastructural identification of cholinergic neurons in the external cuneate nucleus of the gerbil: acetylcholinesterase histochemistry and choline acetyltransferase immunocytochemistry

Summary Using acetylcholinesterase histochemical and choline acetyltransferase immunocytochemical localization methods, this study has provided conclusive evidence for the existence of cholinergic neurons in the external cuneate nucleus of gerbils. By light microscopy, both acetylcholinesterase and choline acetyltransferase labelling was confined to the rostral portion of the external cuneate nucleus. Ultrastructurally, acetylcholinesterase reaction products were found in the nuclear envelope, cisternae of rough endoplasmic reticulum and Golgi saccules of some somata and large dendrites as well as in the membranes of small dendrites, myelinated axons and axon terminals. These neuronal elements were also stained for choline acetyltransferase; immunoreactivity was associated with nuclear pores, nuclear envelope, perikaryal membrane and all the membranous structures within the cytoplasm. Of the total choline acetyltransferase-labelled neuronal profiles analysed, 79% were myelinated axons, 15% dendrites, 4% somata and 2% axon terminals. The immunostained axon terminals consisted of two types containing either round (Rd type; 62.5%) or pleomorphic (Pd type; 37.5%) vesicles. Both were associated directly with choline acetyltransferase-positive dendrites. In contrast to the paucity of choline acetyltransferase-labelled axon terminals, numerous choline acetyltransferase-positive myelinated axons were present. It may thus be hypothesized that most, if not all, of the external cuneate nucleus cholinergic neurons are projection cells; such cells may give rise to axonal collaterals which synapse onto their own dendrites for possible feedback control. Choline acetyltransferase-positive dendrites were contacted by numerous unlabelled presynaptic boutons, 60% of which contained round or spherical synaptic vesicles (Rd boutons) and 40% flattened vesicles (Fd boutons), suggesting that these neurons are under strong inhibitory control. The preferential concentration of cholinergic components in the rostral external cuneate nucleus may be significant in the light of the highly organized somatotopy in the external cuneate nucleus and its extensive efferent projections to medullary autonomic-related nuclei. Our results suggest that the cholinergic neurons may be involved in somatoautonomic integration.     

Pregnancy is associated with extensive adrenergic nerve degeneration in the uterus. An electronmicroscopic study in the guinea-pig

The uterus of virgin guinea-pigs is supplied with a well-developed system of adrenergic nerves, characterized by 50 nm diameter synaptic vesicles whose electron-density is enhanced following administration of 5-hydroxydopamine. In the course of pregnancy, an increasing number of nerves with signs of various stages of degeneration are seen, varying from a slight condensation of the axonal content or myelin figures, to highly osmiophilic dense bodies lacking plasma membrane and with no organelles discernible. Incipient degeneration in a small number of axons is evident already in early pregnancy (up to 10 days post coitum). At late pregnancy (40–50 days post coitum), almost all adrenergic nerve terminals have disappeared as a consequence of degeneration, so that only a few isolated heavily degenerated axon terminals remain visible. Neither normal nor degenerating axons are found in the myometrium at full term. The degenerative changes occur earlier and are, at the various pregnancy stages, more pronounced in that part of the uterus surrounding and expanded by the fetus, compared to those segments of the uterine wall separating the fetuses.Thus, the normal neuromuscular relationship in the uterus during such an entirely physiological condition as pregnancy is lost entirely, in contrast to other sympathetically innervated organs, where the nerve plexus usually keeps pace with volume changes in the effector tissue.     

Structural features of synaptic connections between descending systems and spinal neurons in the cat

The degeneration of axon terminals of the lateral (cortico and rubrospinal) and ventral (vestibulo- and reticulospinal) descending and propriospinal (lateral and ventral funiculus) systems was investigated by electron microscopy in the cat spinal cord. We studied the mean diameters of axon terminals, their arrangement on the neuronal structures in the grey matter, as well as the variety of the destructive changes in synaptic terminals. The average size of the ‘dark’ type degenerating axon terminals of fibers in the lateral descending systems was smaller than that of the ‘light’ type degenerating axon terminals in the medial descending systems. The average size of the both ‘dark’ and ‘light’ type degenerating propriospinal terminals of the ventral funiculus differed from those of the lateral funiculus.The findings concerning the sizes of synaptic terminals of the different descending and propriospinal systems correlate to a certain extent with the electrophysiological data about the nature of their synaptic action upon the spinal neurons.     

Unilateral retrogasserian rhizotomy causes contralateral degeneration in spinal trigeminal nuclei of cats: an ultrastructural study

We are studying the response to injury within the brainstem trigeminal nucleus following trigeminal nerve lesions. We have previously shown with light microscopy and reduced silver stains that unilateral retrogasserian rhizotomy results not only in massive degeneration throughout the ipsilateral spinal trigeminal nucleus; in addition, degeneration is seen in a ventral position at the periobex region (involving caudal pars interpolaris and rostral pars caudalis) in the contralateral spinal trigeminal nucleus. In the present study, we have used electron microscopy to identify the source of the degenerating elements seen bilaterally after unilateral retrogasserian rhizotomy in eight adult felines with survival times ranging from 3 to 20 days. At short survival times (3–7 days) degenerating terminals with round synaptic vesicles (R terminals) and type 1, asymmetric contacts predominate bilaterally, while fewer degenerating terminals with flattened synaptic vesicles (F terminals) and type 2, symmetric contacts are seen. At longer survival times more F terminal degeneration is seen, especially on the contralateral side. Postsynaptic sites and dendrites show minimal alterations. These findings suggest that the degenerating R terminals seen on the contralateral side originate from primary afferents while the degenerating F terminals seen on the contralateral side originate from intrinsic sources involving a crossed internuclear pathway. In addition, the finding of degenerating F terminals may represent a novel form of selective transynaptic change of intrinsic neurons, associated with minimal dendritic or somatic alterations.