Oligodendroglia regulate the regional expansion of axon caliber and local accumulation of neurofilaments during development independently of myelin formation

Axon caliber may be influenced by intrinsic neuronal factors and extrinsic factors related to myelination. To understand these extrinsic influences, we studied how axon-caliber expansion is related to changes in neurofilament and microtubule organization as axons of retinal ganglion cells interact with oligodendroglia and become myelinated during normal mouse brain development. Caliber expanded and neurofilaments accumulated only along regions of the axon invested with oligodendroglia. Very proximal portions of axons within a region of the optic nerve from which oligodendrocytes are excluded remained unchanged. More distally, these axons rapidly expanded an average of fourfold as soon as they were recruited to become myelinated between postnatal days 9 and 120. Unmyelinated axons remained unchanged. Axons ensheathed by oligodendroglial processes, but not yet myelinated, were intermediate in caliber and neurofilament number. That oligodendrocytes can trigger regional caliber expansion in the absence of myelin was confirmed using three strains of mice with different mutations that prevent myelin formation but allow wrapping of some axons by oligodendroglial processes. Unmyelinated axons persistently wrapped by oligodendrocytes showed full axon caliber expansion, neurofilament accumulation, and appropriately increased lateral spacing between neurofilaments. Thus, signals from oligodendrocytes, independent of myelin formation, are sufficient to induce full axon radial growth primarily by triggering local accumulation and reorganization of the neurofilament network.

Properties of the endosomal-lysosomal system in the human central nervous system: disturbances mark most neurons in populations at risk to degenerate in Alzheimer's disease

Specific antibodies and cytochemical markers combined with several imaging and morphometric techniques were used to characterize the endosomal-lysosomal system in mature neurons of the normal human central nervous system and to quantitate changes in its function in Alzheimer's disease. Compartments containing cathespin D (Cat D) and other acid hydrolases included a major subpopulation of mature lysosomes lacking mannose-6-phosphate receptors (MPR) and smaller populations of late endosomes (MPR-positive) and lipofuscin granules (MPR-negative). Antibodies to the pro-isoform of Cat D decorated perinuclear vacuolar compartments corresponding to late endosomes. Neurons and glia contained lysosomes with differing complements of acid hydrolases, implying different processing capabilities. Endosome/lysosome number per unit volume of cytoplasm was relatively well conserved within populations of normal neurons. By contrast, in morphometric analyses of Alzheimer's disease brains, 80-93% of pyramidal cells in the prefrontal cortex (laminae III or V) and hippocampus (CA2, CA3) displayed two- to eightfold higher numbers of hydrolase-positive vacuolar compartments than did corresponding cell populations in age-matched normal brains. Only 5-10% of cerebellar Purkinje cells, a less vulnerable population, showed the same statistically significant elevations. Most affected in these brain regions and in subcortical areas seemed otherwise normal by conventional histological staining and ultrastructural inspection. That both lysosomal and pro-Cat D- and MPR-positive endosomal compartments increased in number demonstrates that the endosomal-lysosomal system is activated markedly in vulnerable neuronal populations of Alzheimer's disease brains and implies that endocytosis or autophagy or both are accelerated persistently at an early stage of cellular compromise, greatly surpassing the degree of activity associated with normal aging. Early activation of the endosomal-lysosomal system represents a biological event potentially linking major etiological factors in Alzheimer's disease, including defective membrane proteins, apolipoprotein E function, and altered amyloid precursor protein processing.

Phosphorylation on carboxyl terminus domains of neurofilament proteins in retinal ganglion cell neurons in vivo: influences on regional neurofilament accumulation, interneurofilament spacing, and axon caliber

The high molecular weight subunits of neurofilaments, NF-H and NF-M, have distinctively long carboxyl-terminal domains that become highly phosphorylated after newly formed neurofilaments enter the axon. We have investigated the functions of this process in normal, unperturbed retinal ganglion cell neurons of mature mice. Using in vivo pulse labeling with [35S]methionine or [32P]orthophosphate and immunocytochemistry with monoclonal antibodies to phosphorylation-dependent neurofilament epitopes, we showed that NF-H and NF-M subunits of transported neurofilaments begin to attain a mature state of phosphorylation within a discrete, very proximal region along optic axons starting 150 microns from the eye. Ultrastructural morphometry of 1,700-2,500 optic axons at each of seven levels proximal or distal to this transition zone demonstrated a threefold expansion of axon caliber at the 150-microns level, which then remained constant distally. The numbers of neurofilaments nearly doubled between the 100- and 150-microns level and further increased a total of threefold by the 1,200-microns level. Microtubule numbers rose only 30-35%. The minimum spacing between neurofilaments also nearly doubled and the average spacing increased from 30 nm to 55 nm. These results show that carboxyl-terminal phosphorylation expands axon caliber by initiating the local accumulation of neurofilaments within axons as well as by increasing the obligatory lateral spacing between neurofilaments. Myelination, which also began at the 150-microns level, may be an important influence on these events because no local neurofilament accumulation or caliber expansion occurred along unmyelinated optic axons. These findings provide evidence that carboxyl-terminal phosphorylation triggers the radial extension of neurofilament sidearms and is a key regulatory influence on neurofilament transport and on the local formation of a stationary but dynamic axonal cytoskeletal network.

The protein phosphatase inhibitor okadaic acid increases axonal neurofilaments and neurite caliber, and decreases axonal microtubules in NB2a/d1 cells

When cells were treated with dbcAMP for 3 days to induce the outgrowth of axonal neurites, the addition of the phosphatase inhibitor okadaic acid (OA; 5 nM) for the last 24 hr markedly increased neurofilament subunit immunoreactivity including phosphate-dependent NF-H epitopes in axonal neurites, increased axonal neurite caliber by approximately 30%, but did not increase neurite contour length. Ultrastructural analysis demonstrated a > 2-fold increase in neurofilaments and indicated that neurofilaments were phosphorylated to a similar extent in the presence and absence of OA. Vimentin immunoreactivity, which undergoes down-regulation during dbcAMP-mediated differentiation, was not increased by OA. OA did not induce the precocious appearance of delayed phosphate-dependent neurofilament epitopes suggesting that it did not induce the activation of additional neurofilament kinases. NF-H subunits from cytoskeletons of OA-treated cells were less susceptible to degradation by an endogenous calcium-dependent protease, providing a possible mechanism for neurofilament accumulation during OA treatment. By contrast, OA decreased axonal neurite microtubules, and eliminated stabilized (acetylated) axonal microtubules. OA treatment at earlier times prevented and reversed neurite outgrowth. Despite increased deposition of phosphorylated neurofilaments, OA did not hasten the development of colchicine resistance to neurites, suggesting that stabilization of the axonal cytoskeletal lattice requires neurofilament-microtubule interaction.

The lysosomal system in neurons. Involvement at multiple stages of Alzheimer's disease pathogenesis

Disturbed lysosomal function may be implicated at several stages of Alzheimer's pathogenesis. Lysosomes and acid hydrolases accumulate in the majority of neocortical pyramidal neurons before typical degenerative changes can be detected, indicating that altered lysosome function is among the earliest markers of metabolic dysfunction in Alzheimer's disease. These early alterations could reflect accelerated membrane and protein turnover, defective lysosome or hydrolase function, abnormal lysosomal trafficking or any combination of these possibilities. Because APP is partly metabolized in lysosomes, early disturbances in lysosomal function could promote the production of abnormal and/or neurotoxic APP fragments within intact cells. Lysosomal abnormalities progressively worsen as neurons begin to degenerate. Based on existing literature on cell death, increased perturbation and instability of the lysosomal system may be expected to contribute to the atrophy and eventual lysis of the neuron. Finally, the release of hydrolase-filled lysosomes and lipofuscin aggregates from dying neurons accounts for the abundant deposition of enzymatically active acid hydrolases of all classes in the extracellular space--a phenomenon that may be unique to Alzheimer's disease. Acting on APP present in surrounding dystrophic neurites, cellular debris and astrocyte processes, dysregulated hydrolases may cleave APP in atypical sequential patterns, thereby generating self-aggregating protease-resistant APP fragments that can be only processed to beta-amyloid. Genetic mutations or posttranslational factors of APP should further enhance the generation of amyloidogenic fragments by a dysregulated lysosomal system. Given that very little, if any, beta-amyloid is detected intracellularly, yet extracellular beta-amyloid is very abundant, our data suggest that the final steps of APP processing and the generation of most beta-amyloid in the brain parenchyma occur extracellularly and may involve one or more lysosomal proteases.

Lysosomal hydrolases of different classes are abnormally distributed in brains of patients with Alzheimer disease

beta-Amyloid formation requires multiple abnormal proteolytic cleavages of amyloid precursor protein (APP), including one within its intramembrane domain. Lysosomes, which contain a wide variety of proteases (cathepsins) and other acid hydrolases, are major sites for the turnover of membrane proteins and other cell constituents. Using immunocytochemistry, immunoelectron microscopy, and enzyme histochemistry, we studied the expression and cellular distributions of 10 lysosomal hydrolases, including 4 cathepsins, in neocortex from patients with Alzheimer disease and control (non-Alzheimer-disease) individuals. In control brains, acid hydrolases were localized exclusively to intracellular lysosome-related compartments, and 8 of the 10 enzymes predominated in neurons. In Alzheimer disease brains, strongly immunoreactive lysosomes and lipofuscin granules accumulated markedly in the perikarya and proximal dendrites of many cortical neurons, some of which were undergoing degeneration. More strikingly, these same hydrolases were present in equally high or higher levels in senile plaques in Alzheimer disease, but they were not found extracellularly in control brains, including those from Parkinson or Huntington disease patients. At the ultrastructural level, hydrolase immunoreactivity in senile plaques was localized to extracellular lipofuscin granules similar in morphology to those within degenerating neurons. Two cathepsins that were undetectable in neurons were absent from senile plaques. These results show that lysosome function is altered in cortical neurons in Alzheimer disease. The presence of a broad spectrum of acid hydrolases in senile plaques indicates that lysosomes and their contents may be liberated from cells, principally neurons and their processes, as they degenerate. Because cathepsins can cleave polypeptide sites on APP relevant for beta-amyloid formation, their abnormal extracellular localization and dysregulation in Alzheimer disease can account for the multiple hydrolytic events in beta-amyloid formation. The actions of membrane-degrading acid hydrolases could also explain how the intramembrane portion of APP containing the C terminus of beta-amyloid becomes accessible to proteases.

Decreased neuronal and increased oligodendroglial densities in Huntington's disease caudate nucleus

Decreased density of neurons was found throughout the head of the caudate nucleus in Huntington's disease (HD), with the most severe neuronal loss early in the disease in the medial region. The density of reactive astrocytes is inversely proportional to the neuronal loss. In cases of mild Huntington's disease which had no identifiable abnormality on conventional neuropathologic evaluation (grade 0), there is a reduction in neuron density without an accompanying reactive astrocytosis. The pattern for decrease in neurons and accompanying astrocytosis suggests that the earliest changes occur in the most medial portion of the head of the caudate nucleus and subsequently sweep laterally across the caudate nucleus to the internal capsule. An increased density of oligodendrocytes is observed in the head of the caudate nucleus for the lower grades (0, 1 and 2). The decreased neuronal and increased oligodendroglial densities may be of significance in understanding the pathogenesis of HD. These altered densities, observed in the absence of reactive astrocytosis, suggest that these changes may not represent recent effects of disease, but rather that HD gene expression may influence brain cell densities from early in the life of the gene carrier.

Morphometric analysis of the prefrontal cortex in Huntington's disease

We performed a morphometric analysis of cresyl violet-stained sections from the dorsolateral prefrontal cortex of 81 patients with Huntington's disease (HD) (grades 2, 3, and 4) and 23 age-matched normal controls. We counted large pyramidal neurons, small neurons, astrocytes, oligodendroglia, and microglia under the guidance of a specifically predefined set of morphologic criteria for each cell type and recorded the thickness of each cortical layer. Our results demonstrate a selective and progressive loss of a subset of the large pyramidal neurons in cortical layers III, V, and VI of HD patients, and a decrease in the thickness of the respective cortical laminae. A genetically determined, cell-autonomous degeneration of cortical neurons could constitute the primary pathologic process. However, the loss of only a fraction of pyramidal cells suggest a parallel, or an alternative, possibility of a retrograde degeneration of cortical neurons that project solely, or principally, to the site of primary degeneration in caudate nuclei.

Morphological assessment of neuronal aggregates in the striatum of the rat

Regional variations in cell-packing density, culminating in the formation of cell clusters, is now a recognized morphological characteristic of the striatum that has been correlated, in some instances, with either regional histochemical variations or the distribution pattern of afferent fiber systems, or both. Within these cluster regions a further level of organization exists, in the form of discrete neuronal aggregates. The light microscopic morphology of these neurons and the nature of their intercellular contacts at the electron microscope level form the focus of this report. The neurons composing such aggregates are characterized by contiguous soma-somatic or soma-dendritic contact with extended regions of junctionlike symmetrical and consistent contacts where the distance between the cytoplasmic membranes of apposing neurons narrows to as close as 7 nm. Coated vesicles close to the contact areas are common. Three-dimensional computer reconstructions of serial 1 micron sections through aggregates in either the caudatoputamen or nucleus accumbens reveal "chains" of contiguous cells that frequently involve as many as 60 neurons. These contiguous cell aggregates are discrete entities within the larger clusters or islands. It is postulated that the cellular aggregates may represent the fundamental level of striatal organization and may be local modules for intrinsic information processing, modifying extrinsic data processed through the biochemical compartmentalization of the striatum imparted by striosomes, neuropeptides, and dopaminergic, thalamic and cortical afferents.

Aluminum salts induce the accumulation of neurofilaments in perikarya of NB2a/dl neuroblastoma

NB2a/dl neuroblastoma cells were exposed to aluminum chloride or aluminum lactate (0.1-1 mM) for 3 and 6 days. Additional cultures were exposed to aluminum salts as the cells were stimulated to elaborate axonal neurites by dibutyryl cyclic AMP. By phase-contrast microscopy, aluminum salts had no effect on the morphology of undifferentiated (NB2a(-] or differentiated (NB2a(+] cells, or on neuritic elaboration and maintenance. Silver straining by the Bielschowsky method, however, demonstrated argyrophilic accumulations in perikarya of many NB2a(-) and NB2a(+) cells treated with aluminum salts. At the ultrastructural level, whorls of intermediate filaments were the most prominent abnormalities in neuronal perikarya. Although phosphorylated high-molecular weight neurofilament subunits (NF-H) are normally detected by immunocytochemical analyses only within axonal neurites of NB2a/dl cells, aluminum salt treatment caused the detection of phosphorylated epitopes of NF-H within perikaryal of NB2a(-) and NB2a(+) cytoskeletons, suggesting that the argyrophilic filamentous accumulations are composed at least partly of phosphorylated NF-H.

Synaptic rearrangements in medial prefrontal cortex of haloperidol-treated rats

The effects of daily administration of haloperidol for 16 weeks on the structure of layer VI in medial prefrontal cortex of rat was performed at the light and electron microscopic levels. At the light microscopic level, no difference in either the size or the density of neurons was observed. At the electron microscopic level, the mean dendritic calibre of haloperidol-treated rats was twice that observed in control animals, but this was due to a selective loss of small-calibre dendritic profiles. Rats treated with neuroleptic also showed a reduction in axon terminals with asymmetric postsynaptic membrane specializations, which, in control animals, were preferentially associated with small-calibre dendritic profiles. These small-calibre dendritic profiles were found to be spines rather than small terminal dendritic shafts. An increase in axon terminals showing no membrane specialization on larger dendritic profiles also occurred in rats treated daily with the neuroleptic. The data suggest the possibility that haloperidol may have induced a relocation of asymmetric terminals from resorbed spinous processes to larger dendritic branches with the concomitant loss of their postsynaptic membrane specialization.

The effects of haloperidol on synaptic patterns in the rat striatum

A morphometric analysis of the corpus striatum of rats chronically treated with haloperidol was performed at the light and electron microscopic levels. Although the density of striatal neurons was unchanged in the haloperidol-treated group, there was a small increase in neuronal size (13%). This change in cell size was paralleled by a trend towards larger dendrite calibres occurring in the drug-treated animals. The distribution curve for axon terminal size indicated that 12% of the overall population was shifted from a range with a median size of 0.8 micron 2 to one with 1.6 micron 2 in the drug-treated group. This increase in size of some striatal terminals was accompanied by a concomitant increase in numbers of their associated synaptic vesicles, resulting in a similar density of vesicles for both control and drug-treated animals.

Haloperidol-induced plasticity of axon terminals in rat substantia nigra

An electron micrographic morphometric analysis of nerve endings in substantia nigra of rats repeatedly treated with haloperidol was performed. Although most parameters showed no difference, drug-treated animals exhibited a significant shift in the distribution of relative numbers of axon terminals, suggesting neuroleptic-induced axon-collateral sprouting.

The cytology of dopaminergic and nondopaminergic neurons in the substantia nigra and ventral tegmental area of the rat: a light- and electron-microscopic study

The results of this study support the conclusion that dopaminergic cells can be distinguished from non-dopaminergic cells, at both the light- and electron-microscopic level, by cytological features, and particularly by the pattern of Nissl substance. In both the substantia nigra and the ventral tegmental area, two main categories of cell type can be identified in Nissl preparations: (1) dark-staining, basophilic cells with large masses of Nissl substance and (2) light-staining cells with more translucent cytoplasm. The following findings provide evidence that the basophilic cells of both substantia nigra and ventral tegmental area are the dopaminergic cells. (1) There is a good correlation between the topographic distribution of basophilic cells and that of dopaminergic cells mapped by both histofluorescence and immunohistochemical methods. (2) After unilateral destruction of the dopaminergic neurons by intracerebral injection of 6-hydroxydopamine in the dopaminergic pathway, the basophilic cells in the substantia nigra and ventral tegmental area disappeared on the lesion side, while the lighter-staining cells appeared unaffected. (3) In normal rats, and in rats with unilateral 6-hydroxydopamine lesions, intraventricular injection of [3H]norepinephrine was used for specific labeling of dopaminergic neurons. In autoradiograms of semithin sections, such labeling was observed only in dark-staining and not in light-staining cells, and in cases of unilateral 6-hydroxydopamine lesion was totally absent on the lesion side. Electron-microscopy showed much of the cytoplasm of the basophilic dopaminergic cells to be densely filled with free ribosomes associated with large, well organized complexes of rough endoplasmic reticulum. The cytoplasm of the light, non-dopaminergic cells contains only sparse free ribosomes and small, widely spaced aggregates of rough endoplasmic reticulum. Both cell types occur in a similar variety of size and shape.