The basis for silver staining of synapses of the mammalian spinal cord: a light and electron microscope study

Ciliate Research. From Myth to Trendsetting Science

This special issue of the Journal of Eukaryotic Microbiology (JEM) summarizes achievements obtained by generations of researchers with ciliates in widely different disciplines. In fact, ciliates range among the first cells seen under the microscope centuries ago. Their beauty made them an object of scientia amabilis and their manifold reactions made them attractive for college experiments and finally challenged causal analyses at the cellular level. Some of this work was honored by a Nobel Prize. Some observations yielded a baseline for additional novel discoveries, occasionally facilitated by specific properties of some ciliates. This also offers some advantage in the exploration of closely related parasites (malaria). Articles contributed here by colleagues from all over the world encompass a broad spectrum of ciliate life, from genetics to evolution, from molecular cell biology to ecology, from intercellular signaling to epigenetics etc. This introductory chapter, largely based on my personal perception, aims at integrating work presented in this special issue of JEM into a broader historical context up to current research.

Circuits and Synapses: Hypothesis, Observation, Controversy and Serendipity - An Opinion Piece

More than a century of dedicated research has resulted in what we now know, and what we think we know, about synapses and neural circuits. This piece asks to what extent some of the major advances - both theoretical and practical - have resulted from carefully considered theory, or experimental design: endeavors that aim to address a question, or to refute an existing hypothesis. It also, however, addresses the important part that serendipity and chance have played. There are cases where hypothesis driven research has resulted in important progress. There are also examples where a hypothesis, a model, or even an experimental approach - particularly one that seems to provide welcome simplification - has become so popular that it becomes dogma and stifles advance in other directions. The nervous system rejoices in complexity, which should neither be ignored, nor run from. The emergence of testable "rules" that can simplify our understanding of neuronal circuits has required the collection of large amounts of data that were difficult to obtain. And although those collecting these data have been criticized for not advancing hypotheses while they were "collecting butterflies," the beauty of the butterflies always enticed us toward further exploration.

Rainer Walter Guillery. 28 August 1929—7 April 2017

Rainer (Ray) Guillery was a remarkably productive neuroscientist and as such left an indelible mark on the field, both in terms of his direct contributions and also through his success at mentoring and nurturing young scholars who went on to successful careers of their own. Ray's work profoundly advanced our understanding of the related fields of development and thalamocortical functioning; his work was highly imaginative and insightful; and he was a cherished colleague and role model for his many former students and friends in the field. Ray's scholarly efforts were carried out on three continents. He trained initially in London and, after serving on the faculties at the Universities of Wisconsin and Chicago in the United States, he returned to England at the University of Oxford. After retiring from his Oxford post, he went back as a visiting scholar to the University of Wisconsin, and then moved to a post at the University of Marmara in Turkey, which is located in the Asian sector of Istanbul. He finally returned to Oxford in an emeritus capacity and remained there until his death.

Excitable neurofibrils and the problem of identifying the structure of central excitatory synapses in the nineteenth century

Neurofibrils, identified after staining with Cajal's reduced silver nitrate, for example, were thought by many senior histologists in the nineteenth and early-twentieth centuries to conduct action potentials. There was no basis for this popular idea, although it was the impetus for intense study of the "neurofibrillar network" within neurons by Golgi, Cajal, Freud, and many others. Here, I trace the way in which this "excitable neurofibrillary" hypothesis led to major problems in the attempt by histologists to identify the central excitatory synapse, postulated by Sherrington on functional grounds and eventually described by Berkley.

Otto Friedrich Karl Deiters (1834-1863)

Otto Deiters, for whom the lateral vestibular nucleus and the supporting cells of the outer auditory hair cells were named, died in 1863 aged 29. He taught in the Bonn Anatomy Department, had an appointment in the University Clinic, and ran a small private practice. He published articles on the cell theory, the structure and development of muscle fibers, the inner ear, leukaemia, and scarlet fever. He was the second of five surviving children in an academic family whose private correspondence revealed him to be a young man with limited social skills and high ambitions to complete a deeply original study of the brainstem and spinal cord. However, first his father and then his younger brother died, leaving him and his older brother responsible for a suddenly impecunious family as he failed to gain academic promotion. Otto died of typhus two years after his younger brother's death, leaving his greatest scientific achievement to be published posthumously. He showed that most nerve cells have a single axon and several dendrites; he recognized the possibility that nerve cells might be functionally polarized and produced the first illustrations of synaptic inputs to dendrites from what he termed a second system of nerve fibers.

Neura, nerves, nerve fibers, neurofibrils, microtubules: multidimensional routes of pain, pleasure, and voluntary action in images across the ages

Available records indicate that the human body has always been conceived, in different periods and cultures, as spanned by multiple channels for internal communication and coherent functioning as a unit-"meridians" in treatises of Chinese medicine, metu in Egyptian papyri, srotas in Ayurvedic Indian texts, and neura in the Western scientific heritage from ancient Greece. Unfortunately, the earliest extant figurative depictions of such pathways of general control, complementary to the blood vessels, are late medieval copies of old crude sketches that attempted to show the main anatomico-physiological systems. The scarcity of adequate illustrations was more than compensated in the Renaissance, when the efforts of both artists and anatomists for the first time produced basically correct renditions of the human nervous system and many other bodily structures. As attention was next focused on microscopic structure as a requisite to understand physiological mechanisms, during the Enlightenment the nerves were revealed to consist of numerous thin tubes or fibers aligned in parallel. Improved microscopy techniques in the nineteenth century led to discovering and delineating still finer fibrils coursing along the cores of the nerve fibers themselves. Electron microscopy, developed throughout the twentieth century, recognized some of these fibrils within nerve fibers as being also tubular. All the progressive stages in understanding nerve construction, at increasingly more detailed scales, have been accompanied by technological advances and by debate about the structure and function relationship. And every step has been a source of amazing imagery.

Cell proliferation and cytoarchitectural remodeling during spinal cord reconnection in the fresh-water turtle Trachemys dorbignyi

In fresh-water turtles, the bridge connecting the proximal and caudal stumps of transected spinal cords consists of regenerating axons running through a glial cellular matrix. To understand the process leading to the generation of the scaffold bridging the lesion, we analyzed the mitotic activity triggered by spinal injury in animals maintained alive for 20-30 days after spinal cord transection. Flow cytometry and bromodeoxyuridine (BrdU)-labeling experiments revealed a significant increment of cycling cells around the lesion epicenter. BrdU-tagged cells maintained a close association with regenerating axons. Most dividing cells expressed the brain lipid-binding protein (BLBP). Cells with BrdU-positive nuclei expressed glial fibrillary acidic protein. As spinal cord regeneration involves dynamic cell rearrangements, we explored the ultra-structure of the bridge and found cells with the aspect of immature oligodendrocytes forming an embryonic-like microenvironment. These cells supported and ensheathed regenerating axons that were recognized by immunocytological and electron-microscopical procedures. Since functional recovery depends on proper impulse transmission, we examined the anatomical axon-glia relationships near the lesion epicenter. Computer-assisted three-dimensional models revealed helical axon-glial junctions in which the intercellular space appeared to be reduced (5-7 nm). Serial-sectioning analysis revealed that fibril-containing processes provided myelinating axon sheaths. Thus, disruption of the ependymal layer elicits mitotic activity predominantly in radial glia expressing BLBP on the lateral aspects of the ependyma. These cycling cells seem to migrate and contribute to the bridge providing the main support and sheaths for regenerating axons.

Observations of synaptic structures: origins of the neuron doctrine and its current status

The neuron doctrine represents nerve cells as polarized structures that contact each other at specialized (synaptic) junctions and form the developmental, functional, structural and trophic units of nervous systems. The doctrine provided a powerful analytical tool in the past, but is now seldom used in educating neuroscientists. Early observations of, and speculations about, sites of neuronal communication, which were made in the early 1860s, almost 30 years before the neuron doctrine was developed, are presented in relation to later accounts, particularly those made in support of, or opposition to, the neuron doctrine. These markedly differing accounts are considered in relation to limitations imposed by preparative and microscopical methods, and are discussed briefly as representing a post-Darwinian, reductionist view, on the one hand, opposed to a holistic view of mankind as a special part of creation, on the other. The widely misunderstood relationship of the neuron doctrine to the cell theory is discussed, as is the degree to which the neuron doctrine is still strictly applicable to an analysis of nervous systems. Current research represents a 'post-neuronist' era. The neuron doctrine provided a strong analytical approach in the past, but can no longer be seen as central to contemporary advances in neuroscience.

Recurring views on the structure and function of the cytoskeleton: a 300-year epic

Some unnoticed or seldom remembered precedents of current views on biological motion and its structural bases are briefly outlined, followed by a concise recapitulation of how the present theory has been constructed in the last few decades. It is shown that the evolution of the concept of fibers as main constituents of living matter led to hypothesizing microscopic structures closely resembling microtubules in the 18th century. At the beginning of this period, fibers sliding over each other and driven by interposed moving elements were envisioned as the cause of muscle contraction. In the following century, an account of the mechanism of myofibril contraction visualized longitudinal displacements of myosin-containing submicroscopic rodlets. The existence of fibrils in the protoplasm of non-muscle cells, a subject of long debate in the second half of the 19th century, was virtually discarded as irrelevant or fallacious 100 years ago. The issue resurfaced in the early 1930s as a theoretical notion--the cytosquelette--nearly two decades before intracellular filamentous structures were first observed with electron microscopy. The role originally assumed for such fibrils as signal conductors is nowadays being reappraised, although under new interpretations with a much wider significance including modulation of gene expression, morphogenesis, and even consciousness. Since all of the above ancestral conceptions were eventually abandoned, the corresponding current views are, to a certain extent, recurrent.

The fine structure of the Purkinje cell

This paper describes the fine structure of the Purkinje cell of the rat cerebellum after fixation by perfusion with 1 per cent buffered osmium tetroxide. Structures described include a large Golgi apparatus, abundant Nissl substance, mitochondria, multivesicular bodies, osmiophilic granules, axodendritic and axosomatic synapses, the nucleus, the nucleolus, and the nucleolar body. A new and possibly unique relationship between mitochondria and subsurface cisterns is described. Possible functional correlations are discussed.

Electron microscopy of optic nerves and optic lobes of Octopus and Eledone

Each optic nerve contains several bundles of axons. The axons have their surface membranes directly apposed and the bundles lie in troughs of the elongated Schwann cells. The axons have pronounced varicosities along their length. The axons enter the optic lobe and run between the granule cells to synapse in the plexiform zone. The granule cells are small neurons. Their cytoplasmic organelles include endoplasmic reticulum, ribosomes, agranular reticulum and of special interest, oval or spherical bodies with a lamellated cortex and granular medulla. The elongated varicose presynaptic bags of the optic axons contain mitochondria in the proximal region, numerous synaptic vesicles and, sometimes, neurofilaments. Below the mitochondrial zone, synaptic contacts are made with small spines invaginated into the bags. The spines probably originate from the trunks of the granule cells. Tunnel fibres that are probably trunks of the outer granule cells, run through channels in the synaptic bags.

AN ELECTRON MICROSCOPE STUDY OF CULTURED RAT SPINAL CORD

Explants prepared from 17- to 18-day fetal rat spinal cord were allowed to mature in culture; such preparations have been shown to differentiate and myelinate in vitro (61) and to be capable of complex bioelectric activity (14–16). At 23, 35, or 76 days, the cultures were fixed (without removal from the coverslip) in buffered OsO₄, embedded in Epon, sectioned, and stained for light and electron microscopy. These mature explants generally are composed of several strata of neurons with an overlying zone of neuropil. The remarkable cytological similarity between in vivo and in vitro nervous tissues is established by the following observations. Cells and processes in the central culture mass are generally closely packed together with little intervening space. Neurons exhibit well developed Nissl bodies, elaborate Golgi regions, and subsurface cisternae. Axosomatic and axodendritic synapses, including synaptic junctions between axons and dendritic spines, are present. Typical synaptic vesicles and increased membrane densities are seen at the terminals. Variations in synaptic fine structure (Type 1 and Type 2 synapses of Gray) are visible. Some characteristics of the cultured spinal cord resemble infrequently observed specializations of in vivo central nervous tissue. Neuronal somas may display minute synapse-bearing projections. Occasionally, synaptic vesicles are grouped in a crystal-like array. A variety of glial cells, many apparently at intermediate stages of differentiation, are found throughout the otherwise mature explant. There is ultrastructural evidence of extensive glycogen deposits in some glial processes and scattered glycogen particles in neuronal terminals. This is the first description of the ultrastructure of cultured spinal cord. Where possible, correlation is made between the ultrastructural data and the known physiological properties of these cultures.

SOME OBSERVATIONS ON THE FINE STRUCTURE OF THE LATERAL LINE ORGAN OF THE JAPANESE SEA EEL LYNCOZYMBA NYSTROMI

The fine structure of the lateral line organ of the Japanese sea eel Lyncozymba nystromi has been studied with the electron microscope. The sensory epithelium of the lateral line organ consists of a cluster of two major types of cells, the sensory hair cells and the supporting cells. The sensory cell is a slender element with a flat upper surface provided with sensory hairs, Two different types of synapses are distinguished on the basal surface of the receptor cell. The first type is an ending without vesicles and the second type is an ending with many vesicles. These are presumed to correspond to the afferent and the efferent innervations of the lateral line organ. The fine structure of the supporting cells and the morphological relationship between the supporting cells and the receptor cells were observed. The possible functions of the supporting cells are as follows: (a) mechanical and metabolic support for the receptor cell; (b) isolation of the individual receptor cell; (c) mucous secretion and probably cupula formation; (d) glial function for the intraepithelial nerve fibers. Both myelinated and unmyelinated fibers were found in the lateral line nerve. The mode of penetration of these fibers into the epithelium was observed.

Expression of neurofilament proteins by horizontal cells in the rabbit retina varies with retinal location

Classical neurofibrillar staining methods and immunocytochemistry with antibodies to the light, medium and heavy chain subunits of the neurofilament triplet have been used for in situ and in vitro investigation of the organization of neurofilaments in A- and B-type horizontal cells of the adult rabbit retina. Surprisingly, their expression and organization within a cell is dependent on its location along the dorso-ventral axis of the retina. A-type horizontal cells in superior retina consistently stained with a wide variety of neurofibrillar methods to reveal neurofibrillar bundles, which immunocytochemistry showed to contain all three neurofilament subunits. A-type horizontal cells in inferior retina were uniformly refractory to neurofibrillar staining, although they expressed all three subunits. However, there was less of the light and medium subunits; the organization of the filaments into bundles (neurofibrils) is minimal. B-type horizontal cells could not be stained with any neurofibrillar method and were not recognizable by in situ immunocytochemistry. However, B-type cells could be seen to express all three subunits in vitro, but the expression of the light and medium subunits was weak. There was only a slight difference between B-type cells taken from superior and inferior retina. Combined with the results of recent transfection studies, these findings suggest that the amount of the light neurofilament subunit present in a horizontal cell determines its content of neurofibrillar bundles, and that rabbit horizontal cells may contain more neurofilament protein, particularly of the heavy subunit, than is used for neurofilament formation.(ABSTRACT TRUNCATED AT 250 WORDS)

The neurofilament triplet is present in distinct subpopulations of neurons in the central nervous system of the guinea-pig

It is commonly assumed that most, if not all, neurons contain the intermediate filament protein class known as the neurofilament protein-triplet. The following study investigated the distribution of neurofilament protein-triplet immunoreactivity in selected regions of the guinea-pig central nervous system using monoclonal antibodies directed against phosphorylation-independent epitopes on the three subunits under optimal tissue processing conditions. Neurofilament protein-triplet immunoreactivity was present in distinct subpopulations of neurons in the cerebellar cortex, neocortex, hippocampal formation, retina, striatum and medulla oblongata. In many of these regions, labelled neurons represented only a small proportion of the total. The selective distribution of this intermediate filament protein class was confirmed in double-labelling experiments using antibodies to the neurofilament protein-triplet in combination with antibodies to other neuronal markers. The distribution of neurofilament protein-triplet immunoreactivity also correlated with the distribution of staining observed with a silver impregnation method based on Bielschowsky. The present results in combination with previous observations have demonstrated that the neurofilament protein-triplet is found in specific subclasses of neurons in different regions of the nervous system. Content of this intermediate filament protein class does not appear to be correlated with neuronal size or length of projection. These results also suggest that the selectivity of staining between neuronal classes observed with classical silver impregnation methods may be due to the presence or absence of the neurofilament protein-triplet. The present results may also provide a new perspective on the basis of the selective vulnerability of neurons in degenerative diseases.

Neurofilament protein triplet immunoreactivity in the dorsal root ganglia of the guinea-pig

Immunoreactivity for the neurofilament protein triplet was investigated in neurons of the dorsal root ganglia of the guinea-pig by using a battery of antibodies. In unfixed tissue, nearly all neurons in these ganglia demonstrated some degree of neurofilament protein triplet immunoreactivity. Large neurons generally displayed intense immunoreactivity, whereas most small to medium-sized neurons showed faint to moderate immunoreactivity. Double-labelling immunofluorescence demonstrated that most antibodies to the individual subunits of the neurofilament protein triplet had the same distribution and intensity of labelling in sensory neurons. Increasing durations of tissue fixation in aldehyde solutions selectively diminished neurofilament protein triplet immunoreactivity in small to medium-sized neurons. Double-labelling with neurofilament protein triplet antibodies in combination with antibodies to other neuronal markers, such as neuron-specific enolase, substance P and tyrosine hydroxylase, showed that tissue processing conditions affect the degree of co-localization of immunoreactivity to the neurofilament protein triplet and to these other neuronal markers. These results indicate that, with a judicious manipulation of the duration of tissue fixation, neurofilament protein triplet immunoreactivity can be used in combination with other neuronal markers to distinguish groups of neurons according to their size and chemical coding.

Early degeneration and sprouting at the rat neuromuscular junction following acrylamide administration

Prolonged acrylamide administration produces motor nerve-terminal branch degeneration and impairs axonal outgrowth following nerve crush. It is unclear how early terminal branch degeneration is initiated and whether there is a compensatory regenerative response at the neuromuscular junction (NMJ). A modified Pestronk and Drachman silver-acetylcholinesterase strain was used to carry out a detailed morphometric analysis of the NMJ in soleus and lumbrical muscles. Rats were given 3, 5, or 10 doses of acrylamide, 35 mg/kg/day, by intraperitoneal injection, 5 days/week, and killed 4, 7, or 14 days after the first dose, respectively. Degenerating terminal branches were evident in soleus NMJ after only three doses of acrylamide. Diminished synaptic vesicle content, neurofilament accumulations and tubulo-vesicular profiles were evident after three doses. At later time points, degenerating terminals contained few synaptic vesicles and were engorged with neurofilaments. Endplate lengthening, indicative of denervation supersensitivity, accompanied degeneration. Terminal sprouting proliferated after 3 and 5 doses but was less prominent after 10 doses. Although similar changes occurred in the lumbrical muscle, they were not initiated until after 5 doses. These experiments reveal that pathological changes in terminal branches commence earlier and after a lower cumulative dose of acrylamide than previously reported and suggest that acrylamide exerts a primary effect at motor nerve-terminal branches. Early, vigorous terminal sprouting indicates that acrylamide does not prevent the initiation of regeneration, but with prolonged treatment does cause degeneration of maturing sprouts.

Neurofilament protein-triplet immunoreactivity in distinct subpopulations of peptide-containing neurons in the guinea-pig coeliac ganglion

A battery of polyclonal and monoclonal antibodies raised against the triplet of identified neurofilament protein subunits was used to investigate neurofilament protein immunoreactivity in neurons of the guinea-pig coeliac ganglion. Using optimal conditions of fixation and tissue processing for each antibody we found that only 20% of the postganglionic sympathetic neurons in the guinea-pig coeliac ganglion contain neurofilament protein-triplet immunoreactivity. Double labelling with neurofilament protein-triplet antibodies raised in different species demonstrated that all of these antibodies labelled the same population of neurons. Double labelling using mouse monoclonal antibodies against neurofilament proteins in combination with rabbit polyclonals to neuronal markers showed that neurofilament protein-triplet immunoreactivity is restricted to specific chemically coded subpopulations of noradrenergic neurons. Approximately 52% of neurons in the ganglion contain neuropeptide Y and are presumed vasomotor neurons projecting to blood vessels in the submucosa of the small intestine. Virtually none of the neuropeptide Y-containing neurons were labelled with neurofilament protein-triplet antibodies. Neurons that contain somatostatin (21%) project to the submucous ganglia of the small intestine. Approximately two-thirds of neurons containing somatostatin are immunoreactive for the neurofilament protein-triplet. The other postganglionic neurons in the ganglion (27%) project to the myenteric plexus of the small intestine and do not contain either neuropeptide Y or somatostatin. Approximately a quarter of these neurons were labelled with neurofilament protein-triplet antibodies. These results suggest that the neurofilament protein-triplet may not be an intrinsic component of the cytoskeleton of all neurons. Furthermore the idea of a chemical coding of neurons should be extended to cytoskeletal proteins. The finding that these neurofilament proteins are confined to specific neuronal subpopulations has important implications for the search for a role of the neurofilament protein-triplet in neurons, for the interpretation of classical neurohistological silver impregnation techniques which appear to stain only neurofilament protein-triplet-containing neurons, as well as for neuropathological conditions that may involve these proteins in disease processes.

The neuronal response to injury as visualized by immunostaining of class III beta-tubulin in the rat

The neuronal response to trauma of the brain and spinal cord was examined by staining sections of injured central nervous system (CNS) with a monoclonal antibody (TuJ1) that recognizes class III beta-tubulin exclusively. Because class III beta-tubulin is expressed by neurons and not by glia, this monoclonal antibody stains neuronal cell bodies, dendrites, axons and axonal terminations darkly with a pale staining background. Thus, the TuJ1 antibody is extremely useful, revealing the fine details of axons and their terminations, as well as significant injury-related alterations in the composition of the somatic cytoskeleton.

Pathology of neuromuscular disorders of the small intestine and colon

A variety of pathological abnormalities of the smooth muscle and myenteric plexus result in clinical syndromes of disordered small intestinal and colonic motility. These pathological abnormalities have been noted by conventional light microscopy and by utilization of Smith's technique for visualizing the myenteric plexus with silver. We have classified the neuromuscular disorders into two major categories, i.e., those affecting the myenteric plexus and those affecting the smooth muscle. The classification is further developed based on the variety of clinicopathological features of the various disorders. Although we can now identify the underlying pathology of these motor disorders and thus understand these illnesses better than we did a decade ago, we have much more to learn. With the great strides being made to understand the normal structure, function, and development of the myenteric plexus and smooth muscle, there is hope that we will be able to learn much more about the etiology and pathogenesis of these neuromuscular disorders in the decade to come.

Alzheimer's disease: paired helical filaments and cytomembranes

Observations were made with the electron microscope on biopsies from the frontal cerebral cortex of four patients showing the clinical symptoms of advanced Alzheimer's disease (AD). Sections from all four biopsies showed neuronal dendrites, and to a lesser extent, perikarya, packed with paired helical filaments (PHFs) and a correlated complete loss of the normal content of microtubules. It was usually impossible to visualize the beginning and end of the PHF since it passed out of the plane of section. However, not infrequently, PHFs could be seen apparently arising at or from the surfaces of cytomembranes. Such membranes (in perikarya or dendrite) often formed irregular stacks or lamellated bodies. These membranes were invariably agranular (i.e. not studded with ribosomes) and so might be considered as pathological forms of smooth endoplasmic reticulum (SER). A correlation is established between the known biochemical nature of PHFs and their postulated membrane origin.

Postnatal growth of motor nerve terminals in muscles of the mouse

A reduced silver stain was used to examine the development of complexity of motor nerve terminals in the postnatal period. Terminals in three histochemically different muscles were examined in mice aged 12 days to 3 years. The total number and total length of intraterminal axon branches increases with age, but only until animals are 3 months old. Terminals become longest and most branched in the histochemically glycolytic tensor fascia latae (TFL) muscle, shortest and least branched in the oxidative diaphragm, and intermediate in the histochemically mixed gluteus muscle. In addition, myelinated terminal branches develop in TFL and to a lesser extent in the gluteus between 1 and 3 months of age. These myelinated branches appear to be produced by nodal sprouting from the penultimate node of Ranvier of the terminal axon, and also by myelination of pre-existing terminal branches. The diameter of muscle fibres also increases until animals are 3 months old, and there is a good correlation between mean fibre diameter and either mean terminal length or mean number of terminal branches when all muscles at all ages are compared. This suggests that terminal growth could be determined by muscle fibre growth; however, within any given muscle there is little or no correlation between the diameter of a muscle fibre and either the length or number of branches of its nerve terminal, suggesting that terminal morphology is not controlled solely by muscle fibre growth. The presence of a myelinated branch in a nerve terminal is also unrelated to fibre diameter within a given muscle, but again when means are compared there are good, but significantly different correlations for the three different muscles. Thus some kind of muscle or nerve type-specific property additional to a general effect of muscle fibre size influences the development of myelinated terminal branches. Between 3 and 12 months of age terminal complexity remains constant or may decrease slightly. At 19 months or older, when mice are becoming senile, a large proportion of synapses have terminal sprouts and muscle fibres become innervated by two or more distinct axons. These changes can be attributed to the death of some motor neurons and sprouting of the remaining axons.

Neurofilament accumulation induced in synapses by leupeptin

The hypothesis that the usual absence of neurofilaments in synaptic terminals is due to their degradation by the calcium-activated protease present in axoplasm was tested by injecting leupeptin, which inhibits the protease, into the optic tectum of goldfish kept at 15 degrees and at 25 degrees C. The resulting accumulation of neurofilaments in synaptic terminals provides in vivo evidence in support of the hypothesis. The significance of these results and the potential uses of this pharmacological tool are discussed.

Coexistence of neurofilaments and vimentin in a neurone of adult mouse retina

Different classes of intermediate filaments are restricted to particular cell types. For example, neurofilaments are found only in neurones, whereas filaments that contain the protein vimentin, which were found in some cells of mesenchymal origin and some forms of glia, are thought to be absent from mature neurones, and present only transiently in early embryonic neurones. However, evidence is presented here of an exception to that rule in the outer plexiform layer of the mouse retina. Double-labelling with antibodies to neurofilaments and vimentin showed that both types of intermediate filaments coexisted in the axonless horizontal cell of that retinal layer, recalling the previous notion that these cells are glial or intermediate between neuronal and glial (reviewed in ref. 10).

The sequential development of nodal sprouts in mouse muscles in response to nerve degeneration

Nodal sprouting in response to axonal degeneration was studied in silver-stained, wholemount preparations of the thin, sheet-like mouse muscles tensor faciae latae (TFL) and the inferior and superior gluteus maximus. Axon degeneration in TFL and gluteus was produced by cutting the L14 spinal nerve (partial denervation). Axon degeneration in the gluteus was also produced by superior gluteal and TFL nerve section (hemidenervation). Two days after partial or hemidenervation motor nerve nodal sprouts begin to appear in the intramuscular nerves. Sprout growth is rapid, since only a small percentage of sprouts are ever seen not to terminate at endplates. Sprouts continue to appear for at least three weeks after partial denervation, when there are up to five times as many endplates innervated by sprouts as by remaining intact axons. Sprouts arise at nodes near the denervated endplates, which they innervate by growing directly down the degenerating nerve. Sprout initiation proceeds sequentially in partly and hemidenervated muscles, since the average length of sprouts contacting endplates increases with time. Analysis of silver-stained muscles by combined light and electron microscopy shows that this sequential development is unlikely to be a consequence of slow growth and maturation of submicroscopic sprouts initiated nonsequentially throughout the intramuscular nerves. The observations are consistent with a nodal sprouting mechanism which requires a cellular or structural change in the denervated Schwann cell pathway to spread disto-proximally from the terminal ends of the nerves and thereby to permit the growth of nodal sprouts. The initiation of sprout growth may require a diffusible substance from degenerating nerve or denervated muscle.

Characterization of the calcium-induced disruption of neurofilaments in rat peripheral nerve

Transverse frozen sections of desheathed rat peripheral nerve were incubated in media of different composition prior to fixation and processing for electron microscopic examination. Neurofilaments remained intact when these tissues were incubated in calcium-free media. A loss of neurofilaments and their replacement by granular debris occurred in myelinated and unmyelinated fibers following incubation in media containing 2 mM calcium. The calcium-mediated disruption of neurofilaments was inhibited by preincubation or incubation with 1 mM p-chloromercuribenzoate (PCMB). The inhibition by preincubation with PCMB could be partially reversed by subsequent preincubation with 10 mM dithioerythritol (DTE). Calcium-mediated breakdown of neurofilaments did not occur after prolonged preincubation in calcium-free media, a finding which suggested that neurofilament disruption was dependent upon a tissue factor which could be lost or inactivated in frozen-sectioned nerve tissues. The findings of the present study provide morphological evidence that neurofilament disruption in mammalian peripheral nerve is mediated by a calcium-activated, PCMB-sensitive enzyme in the axoplasm of myelinated and unmyelinated nerve fibers.

Normal nerve fibers in the barrel region of developing and adult mouse cortex

The pattern of normal nerve fibers associated with barrel-shaped structures in the somatosensory cortex of both young and adult mice, has been studied using a reduced silver method. In adult animals, the "barrel" sides and septa can be seen to contain densely packed bundles of nerve fibers running vertically between layers III and V. In parasagittal sections, these fibers appear as very dark bands between adjacent barrels, while in tangenital sections the fibers, cut in cross-section, appear as rings of dark spots concentrated around the barrel edges. In contrast to this, barrels in immature animals have dark, evenly stained centers and pale, cell dense sides. This immature pattern can first be distinguished in 2-day-old animals and persists until 18 to 19 days. Between 18 and 24 days a change from the immature to the adult pattern occurs with the appearance of darkly stained, fine fibers within layer IV, particularly within the barrel sides. It is suggested that the immature pattern is due, primarily, to the staining of thalamic afferents while the adult pattern appears with the development of intracortical and association fibers. Electron microscopy, on tissue previously treated by the silver method, shows that the silver deposits are mainly attached to longitudinal elements of the axoplasm and not associated with myelin. This may explain the success of this method in showing fibers in young, unmyelinated brains.

Meynert cells in the primate visual cortex

The solitary cells of Meynert are distinguished by their specific location in layer V of the striate cortex, very large size, argyrophilia, and the profusion of neurofilaments in their dendrites and perikarya. They occur with greater frequency in the macular region of the cortex, spaced a minimal distance of 110 mum apart, at a maximum density of about 8000/cm-2. In the perifoveal cortex, Meynert cells are spaced about 400 mum apart and packed at a density of approximately 625/cm-2. Each Meynert cell has an apical dendrite and many large basal dendrites. The perikaryon and primary segments of all dendrites are spine-free; however, more distally a total of 36 000 spines are present, differentially disposed upon the dendritic surfaces. The basal dendrites bear over 77% of the spines on the Meynert cell, although they account for only 66% of the total length of the dendritic arborization. The first part of the apical dendrite is the most densely decorated with appendages, accounting for almost 10% of the spines on the whole dendritic tree. The apical dendrite becomes progressively less spiny as it passes through the superficial part of layers IV and III; less than 2.5% of the total number of spines of the Meynert cell project from this part of the apical dendrite. When the dendrite reaches layer II it bursts into an umbel of rapidly tapering branches. These are highly spinose, accounting for 8-13% of the cell's total, dispersed over only 23% of the linear dendritic length. It is suggested that this differential distribution of thorns can be correlated with the axonal inputs in the various cortical layers, and that the Meynert cell is designed to receive maximal information from layers I and II, and from layers V and VI, which are sources mainly of intracortical inputs. Thus the Meynert cell may be principally concerned with integrative information. In the perifoveal cortex, the basal dendrites of adjacent Meynert cells overlap considerably, and the apical terminal bouquet dendrites do not. In the macular cortex, because of the increased frequency of these neurons, both basaal and apical terminal dendritic fields overlap. A model is developed to illustrate these hypotheses.

Experimental concussion. Ultrastructural and biochemical correlates

Ultrastructural and biochemical alterations were studied in the brainstem reticular formation of animals in which transient coma had been induced by controlled blows to the head. After a period of 7-10 days, animals that did not show obvious injury were artificially respired and sacrificed by perfusion with buffered formalin and glutaraldehyde. Histochemistry and light microscopy revealed chromatolysis of 10-15% of the neurons of pertinent segments of the nucleus giganto cellularis. There was much PAS-positive, diastase-sensitive material in the associated neuropil. Electron miscroscopy of the region confirmed the polysaccharide accumulation in dendrites, presynaptic boutons and preterminal axons. Similar material was found in some astrocytes. A longitudinal microchemical investigation with suitable controls of glycogen concentration in the brainstem demonstrated peak values at 5-7 days after concussion. No significant change in phosphorylase activity was demonstrated. The significance of glycogen accumulation in postconcussive injury and possible mechanisms for its accumulation in relation to changes in electrolyte balance and alterations in Kreb's cycle intermediates are discussed.