Aspects of the organization of neurons and dendritic bundles in primary somatosensory cortex of the rat.

In order to analyze some aspects of the spatial organization in the primary somatosensory cortex of the rat, we have reconstructed the positions of bundles of apical dendrites and neurons in a cortical prisms measuring 0.5 mm x 0.4 mm x cortical thickness, with special reference to a hypothetical columnar organization. Complete series of semithin (0.65 microm) sections were cut, tangentially from the pial surface down to the white matter, stained and digitizalized into a computer and represented as a stack of 2D images. The mean neuron density (N(V)-value) was (60 x 10(3) +/- 15 x 10(3)) neurons/mm3. The mean number of neurons beneath 1 mm2 of cortical surface (NC-value) was (113 x 10(3) +/- 8 x 10(3)) neurons/mm2. Well-defined bundles of apical dendrites emanating from layer V pyramidal cells were observed. The bundles consisted of 3-12 (mean 5 +/- 2) dendrites. The dendrites within a bundle converged while ascending towards the pial surface and reached a maximal close packing in layer IV. Superficially, the packing density decreased again. The mutual positions of the dendrites within the bundles shifted only slightly along their course towards the pial surface. The occurrence of bundles in tangential sections through layer IV was about 190 bundles/mm2 and the average number of neurons per bundle was estimated at approximately 600. However, when calculating Voronoi-diagrams, the number of neurons, which with this mathematical technique, is ascribed to each of the reconstructed dendritic bundles, varied between 200 and 1000. The possibility that the dendritic bundles are centers in cortical cell modules is discussed.

De- and remyelination in spinal roots during normal perinatal development in the cat: a brief summary of structural observations and a conceptual hypothesis.

We have studied the perinatal development of large myelinated axons (adult D > 10 microm) in cat ventral and dorsal lumbosacral spinal roots using autoradiography and electron microscopy (serial section analysis). These axons acquire their first myelin sheaths 2-3 weeks before birth and show nearly mature functional properties first at a diameter of 4-5 microm, i.e. 3-4 weeks after birth. The most conspicuous event during this development takes place around birth, when a transient primary myelin sheath degeneration strikes already well myelinated although short 'aberrant' Schwann cells. The aberrant Schwann cells become completely demyelinated, then measuring about 10 microm in length, and are subsequently eliminated from their parent axons. Morphometry indicates that on average 50% of the Schwann cells originally present along a prospective large spinal root axon suffer elimination. Here it should be noted that in cat lumbo-sacral spinal roots, the longitudinal growth of myelinated Schwann cells that belong to the group containing what will be the largest fibers is on average twice that of their parent axons. The elimination phenomenon is particularly striking in the dorsal roots close to the spinal cord where CNS tissue invades the root for several hundred micrometres. Our observations suggest that, once demyelinated and then eliminated, Schwann cells (i.e. aberrant Schwann cells) colonize neighbouring axons, future myelinated as well as future unmyelinated ones. In the former case the immigrant Schwann cells appear to start myelin production, possibly risking a second demyelination and elimination. We take our observations to indicate that Schwann cells in the cat, during normal development, may switch iteratively between a 'myelin-producing' and a 'non-myelin-producing' phenotype. From a functional point of view the transient presence along a myelinated axon of intercalated unmyelinated segments approximately 10 microm long, due to aberrant Schwann cells, would mean a slowing down of the action potential. The rapid disappearance of aberrant Schwann cells during the two first postnatal weeks could then explain the progressing normalization of the leg-length conduction time.

Intermediate filaments regulate astrocyte motility.

Intermediate filaments (IFs) compose, together with actin filaments and microtubules, the cytoskeleton and they exhibit a remarkable but still enigmatic cell-type specificity. In a number of cell types, IFs seem to be instrumental in the maintenance of the mechanical integrity of cells and tissues. The function of IFs in astrocytes has so far remained elusive. We have recently reported that glial scar formation following brain or spinal cord injury is impaired in mice deficient in glial fibrillary acidic protein and vimentin. These mice lack IFs in reactive astrocytes that are normally pivotal in the wound repair process. Here we show that reactive astrocytes devoid of IFs exhibit clear morphological changes and profound defects in cell motility thereby revealing a novel function for IFs.

Immunostaining of ganglioside GD1b, GD3 and GM1 in rat cerebellum: cellular layer and cell type specific associations.

We have studied the cellular distribution of gangliosides GD1b, GD3 and GM1 in rat cerebellum by immunostaining, using monoclonal antibodies and confocal microscopy. Antibodies against astroglial, neuronal and synaptic vesicle associated molecules were used for colocalization analyses. In the gray matter, the anti-GD1b antibody stained thin strands in the molecular layer (ML), interpreted as Bergman glia fibers based on colocalized staining with anti-glial fibrillary acidic protein (GFAP). The neuropil in the granule (GL) and Purkinje (PL) cell layers was also anti-GD1b positive. The anti-GD3 antibody stained the ML, the neuropil in the GL and PL and also the granule and Purkinje cell bodies, appearing intracytoplasmically and vesicle associated. Anti-GD1b and anti-GD3 staining in the GL glomeruli were colocalized with anti-synaptophysin staining. The anti-GM1 antibody stained cell bodies in the ML but they could not be characterized in colocalization experiments. The GL and PL were not stained with the anti-GM1 antibody. In the white matter, different staining patterns were seen for the gangliosides, the anti-GM1 staining being the most intense. This study shows cellular layer and cell type specific associations of the investigated gangliosides and localization of GD1b and GD3 at synaptic sites, warranting further studies on their role in synaptic mechanisms.

Intermediate filament protein partnership in astrocytes.

Intermediate filaments are general constituents of the cytoskeleton. The function of these structures and the requirement for different types of intermediate filament proteins by individual cells are only partly understood. Here we have addressed the role of specific intermediate filament protein partnerships in the formation of intermediate filaments in astrocytes. Astrocytes may express three types of intermediate filament proteins: glial fibrillary acidic protein (GFAP), vimentin, and nestin. We used mice with targeted mutations in the GFAP or vimentin genes, or both, to study the impact of loss of either or both of these proteins on intermediate filament formation in cultured astrocytes and in normal or reactive astrocytes in vivo. We report that nestin cannot form intermediate filaments on its own, that vimentin may form intermediate filaments with either nestin or GFAP as obligatory partners, and that GFAP is the only intermediate filament protein of the three that may form filaments on its own. However, such filaments show abnormal organization. Aberrant intermediate filament formation is linked to diseases affecting epithelial, neuronal, and muscle cells. Here we present models by which the normal and pathogenic functions of intermediate filaments may be elucidated in astrocytes.

Abnormal reaction to central nervous system injury in mice lacking glial fibrillary acidic protein and vimentin.

In response to injury of the central nervous system, astrocytes become reactive and express high levels of the intermediate filament (IF) proteins glial fibrillary acidic protein (GFAP), vimentin, and nestin. We have shown that astrocytes in mice deficient for both GFAP and vimentin (GFAP-/-vim-/-) cannot form IFs even when nestin is expressed and are thus devoid of IFs in their reactive state. Here, we have studied the reaction to injury in the central nervous system in GFAP-/-, vimentin-/-, or GFAP-/-vim-/- mice. Glial scar formation appeared normal after spinal cord or brain lesions in GFAP-/- or vimentin-/- mice, but was impaired in GFAP-/-vim-/- mice that developed less dense scars frequently accompanied by bleeding. These results show that GFAP and vimentin are required for proper glial scar formation in the injured central nervous system and that some degree of functional overlap exists between these IF proteins.

Redistribution of Schwann cells at the developing PNS-CNS borderline. An ultrastructural and autoradiographic study on the S1 dorsal root of the cat.

In order to test our hypothesis that myelin-forming Schwann cells early during development, after having been eliminated from their parent axons, colonize neighbouring unmyelinated axons, we studied the distribution of Schwann cells at the PNS-CNS border in the feline S1 dorsal spinal root during pre- and postnatal development using electron microscopy and autoradiography. Myelination of axons peripheral to the PNS-CNS border began about 1.5 weeks before birth. The adult distribution of one-third myelinated and two-thirds unmyelinated axons was noted 3 weeks after birth. Analysis based on to-scale reconstructions of axon and Schwann cell samples from the first 6 postnatal weeks gave the following results. (1) CNS tissue appeared in the proximal part of the root around birth and expanded peripherally during the first three postnatal weeks. (2) The number of Schwann cells associated with myelinated axons decreased. (3) The number of Schwann cells associated with unmyelinated axons increased. (4) The mitotic activity of the Schwann cells was low at birth and nil after the first postnatal weak. (5) Apoptotic cell units were virtually absent. (6) Aberrant Schwann cells, i.e. short and very short Schwann cells with distorted and degenerating myelin sheaths, were common. (7) The endoneurial space contained numerous Schwannoid cells i.e. solitary cells surrounded by a basal lamina. (8) Cytoplasmic contacts between unmyelinated axons and aberrant Schwann cells or Schwannoid cells were observed. We take these results to support our hypothesis.

Paranodal Schwann cell mitochondria in spinal roots of the cat. An ultrastructural morphometric analysis.

We have calculated the number of paranodal Schwann cell mitochondria in adult feline ventral and dorsal lumbar spinal roots using ultrastructural serial section analysis. Distinct accumulations of paranodal mitochondria were noted in nerve fibres more than 4-5 microm in diameter. The calculated number of paranodal mitochondria increased linearly with fibre diameter from a few hundred up to 20,000-30,000 per node. A linear increase in the number of paranodal mitochondria per node also appeared as a function of nodal variables such as 'nodal axon membrane area', 'nodal Schwann cell membrane area', and 'node gap extracellular volume'. In large fibres (D = 15-18 microm), a calculated number of about 20,000 paranodal Schwann cell mitochondria were accumulated at each node of Ranvier and related to nodal axon membrane area of about 20 microm2. Our calculations indicate that, on the average, 1000 paranodal Schwann cell mitochondria with a total volume of 6.7 microm3, a total outer membrane area of 250 microm2 and a total inner membrane area of 580 microm2 projected to each microm2 of the nodal axon membrane via the nodal Schwann cell brush border.

Removal of retrogradely transported material from rat lumbosacral alpha-motor axons by paranodal axon-Schwann cell networks.

The aim of this study was to investigate the potential ability of Schwann cells to sequester axonally transported material via so called axon-Schwann cell networks (ASNs). These are entities consisting of sheets of Schwann cell adaxonal plasma membrane that invade the axon and segregate portions of axoplasm in paranodes of large myelinated mammalian nerve fibres. Rat hindlimb alpha-motor axons were examined in the L4-S1 ventral roots using light/fluorescence, confocal laser, and electron microscopy for detection of retrogradely transported red-fluorescent latex nanospheres taken up at a sciatic nerve crush, and intramuscularly injected horseradish peroxidase endocytosed by intact synaptic terminals. Survival times after tracer administration ranged from 27 hours to 4 weeks. During their retrograde transport toward the motor neuron perikarya, organelles carrying nanospheres/peroxidase accumulated at nodes of Ranvier, where they often appeared in close association with the paranodal myelin sheath. Serial section electron microscopy showed that many of the tracer-containing bodies were situated within ASN complexes, thereby being segregated from the main axon. Four weeks after nanosphere administration, several node-paranode regions still showed ASN-associated aggregations of spheres, some of which were situated in the adaxonal Schwann cell cytoplasm. The data establish the ability of Schwann cells to segregate material from motor axons with intact myelin sheaths, using the ASN as mediator. Taken together with our earlier observations that ASNs in alpha-motor axons are also rich in lysosomes, this process would allow a local elimination and secluded degradation of retrogradely transported foreign substances and degenerate organelles before reaching the motor neuron perikarya. In addition, ASNs may serve as sites for disposal of indigestable material.

The existence of a layer IV in the rat motor cortex.

We have reconstructed the laminar pattern of rat primary motor cortex (Fr1) using a computerized analysis system based on the so-called 'optical dissector'. Data were visualized on a graphics terminal. In contrast to current views, which state that there is no prominent layer IV in the motor cortex of the rat, our method of analysis revealed a genuine layer IV consisting of densely packed small neurons.

Monosialoganglioside (GM1) immunofluorescence in rat spinal roots studied with a monoclonal antibody.

Gangliosides are characteristic glycolipid components of plasma cell membranes, especially enriched in the CNS and PNS. In some diseases involving the PNS, in particular motor neuropathies associated with conduction block, IgM autoantibodies against ganglioside GM1 have been implicated as a pathogenic factor. In order to study the GM1 distribution in peripheral nerves we have investigated its in situ localization using a new anti-GM1 monoclonal antibody, GM1:1. Immunization and production of the monoclonal antibody was made by common protocols and binding specificity was investigated by using structurally related glycolipids and modified GM1-molecules. The result showed that an alpha 2-3 bound sialic acid together with a terminal galactose moiety were essential for GM1:1 binding. In situ localization of GM1 in rat dorsal and ventral spinal roots was investigated by conventional immunomicroscopy. GM1 immunoreactivity was the same in both roots and appeared like a finely granular, in places confluent, material confined to Schmidt-Lanterman's incisures, to myelin sheath paranodal end segments and to some extent to the abaxonal Schwann cell cytoplasm; all of these structures are likely to be the target for GM1 antibodies in peripheral neuropathies. Nodal gaps and fibre contours showed a weak non-specific fluorescence. The localization of GM1 to the incisures of Schmidt-Lanterman and the paranodal end segments of the myelin sheaths might indicate a role of gangliosides as adhesion molecules.

Aspects of the quantitative analysis of neurons in the cerebral cortex.

We address three problems concerning the quantitative analysis of nerve cell distribution in the cerebral cortex: (i) preparatory tissue deformation (shrinkage); (ii) difficulties in differentiating between small neurons and astroglia; and (iii) the bias introduced by the counting method. We found that staining with Richardson's solution led to no shrinkage in Vibratome-cut sections of aldehyde-fixed rat brains, but did result in staining of the neurons and left the glial cells unstained. This was in striking contrast to Nissl staining which introduced a linear shrinkage of 20-30% and stained all kinds of cortical cells indiscriminately. A computer-based unbiased counting method was implemented by taking advantage of the stereological procedure referred to as the 'optical disector' (Gundersen, H.J.G. (1986) Stereology of arbitrary particles, J. Microsc., 143: 3-45).

Development of nodes of Ranvier in feline nerves: an ultrastructural presentation.

The ultrastructure of developing nodes of Ranvier and adjacent paranodes of future large myelinated fibers in feline lumbar spinal roots is described. The development starts before birth concurrent with myelination and is finished at the end of the first postnatal month when the nodal regions of future large fibers, now 4-5 microns of diameter, for the first time appear like miniatures of those of their 4 times thicker and fully mature counterparts. At this stage the fibers also begin to show mature functional properties. The latent maturation process is denoted "nodalization" and includes two major events: (1) the formation of a narrow node gap bordered by compact myelin segments and filled with Schwann cell microvilli that interconnect an undercoated nodal axolemma with rapidly increasing accumulations of mitochondria lodging in the longitudinal cords of Schwann cell cytoplasm that is distributed outside a more and more crenated paranodal myelin sheath; (2) the setting of a fixed number of nodes along the axons; an event that includes segmental axonal and myelin sheath degeneration and is concluded by the elimination of supernumerary Schwann cells.

Heterogeneity in the columnar number of neurons in different neocortical areas in the rat.

We have investigated the number of neurons in three neocortical areas of the rat brain. Our results challenge the uniformity concept proposed by Rockel et al. [Brain, 103 (1980) 221-244]. Area Fr1, HL and Oc2 (primary motor, primary somatosensory and secondary visual cortex) from Sprague-Dawley rats were examined. The brains were glutaraldehyde fixed, sectioned in 50 mu m thick sagittal slices and stained in Richardson's solution. The counting was carried out using a computerized system based on the optical disector. The cortical thickness was measured to be 1.9 mm, 1.9 mm, and 1.4 mm in area Fr1, HL, and Oc2, respectively. The number of neurons under 1 mm2 cortical surface was calculated to be 91 100 in Fr1, 133 500 in HL and 106 100 in Oc2. The number of neurons in a volume of tissue 30 x 25 mu m through the depth of the cortex was calculated to be 68 in Fr1, 100 in HL and 80 in Oc2. The density of neurons was calculated to be 48 500 neurons/mm3 in Fr1, 69 400 neurons/mm3 in HL and 76,900 neurons/mm3 in Oc2. There were significant (P < 0.01) differences between all areas regarding both the number of neurons under a certain area of surface as well as the neuron density. The results indicate that there is no basic uniformity in the number of neurons under a certain area of cortical surface.

Horseradish peroxidase in axons of the dorsal funiculi of the cat: distribution after an injection of the enzyme into the dorsal column nuclei.

Horseradish peroxidase (HRP) was injected into the left dorsal column nuclei of adult cats. Large dorsal funiculi axons of the C3, C5, C8 and L7 segments were searched for HRP-activity after 12, 24, 36 and 48h using light and electron microscopy. Accumulations of intra-axonal HRP-positive bodies occurred at nodes of Ranvier in the C3-C8 segments at 12, 24 and 36h and in the L7 segments at 24, 36, and 48h. The accumulations of HRP in three spatio-temporally different consecutive patterns, noted earlier at nodes of Ranvier in the peripheral nervous system (PNS) portion of feline alpha motor axons for more than 70h after an intramuscular injection of the enzyme, were not observed in the present material. We suggest that the differences in the modes in which large PNS and CNS axons interact with retrogradely transported HRP are due to differences in the organization of the respective nodal regions. We also emphasize that endocytosis via axon terminals in the CNS normally represents uptake of material from an extracellular space which is controlled and protected by the blood-brain barrier. This is in contrast to endocytosis via axon terminals in a muscle, which represents uptake of material from an extracellular space openly exposed to influx of different substances from the blood stream.

A method for 3D reconstruction of neuronal processes using semithin serial sections displayed as a cinematographic sequence.

In order to study the organization and distribution of dendrites and axons in the cerebral cortex, we have developed a computer-assisted method for 3D reconstruction of neuronal processes based on serial light microscopic images displayed as a continuous sequence. A series of tangential sections (0.65 micron thick) through rat parietal cortex was aligned, digitized into the computer and then used to build a sequence (stack) of images which was stored to a digital real-time video disk. Apical dendrites located in dendritic bundles in laminae III and IV were traced through the sequence. Two tracing modes were tested: (1) cinematographic mode, in which the image stack was displayed continuously and automatically by the computer at various preset speeds (max. speed: 25 images/s) and (2) stepping mode, in which the interval between each image was varied manually according to the choice of the operator. Coordinates were stored in a database and used to build a 3D reconstruction where apical dendrites were displayed as wires or tubes. Tracing in cinematographic mode was about 3 times faster than tracing in stepping mode. We believe that the former mode exploits the built in 'filtering' capacity of the visual system to perform temporal averaging.

Axonal constriction at Ranvier's node increases during development.

We have studied the ratio between the nodal and the internodal diameter (the dn/d(in) ratio) of large myelinated axons in the L7 ventral spinal root of the cat during pre- and postnatal development using light and electron microscopy. A substantial nodal constriction, dn/d(in) = 0.6, was found at the beginning of myelination, about 2 weeks before birth. The ratio decreased during the subsequent 10 weeks and approached the adult value of 0.47 (SE 0.01, N = 45) in the 8 weeks old kitten. The observations are discussed with respect to the maturation of the nodal region and to our earlier idea that the constricted nodal axon segments of large peripheral myelinated nerve fibres of adult cats and kittens 2 months and more of age are sites capable of interacting with and perhaps even controlling the passage of axonally transported materials.

Mice lacking glial fibrillary acidic protein display astrocytes devoid of intermediate filaments but develop and reproduce normally.

Glial fibrillary acidic protein (GFAP) is the main component of the intermediate filaments in cells of astroglial lineage, including astrocytes in the CNS, nonmyelin forming Schwann cells and enteric glia. To address the function of GFAP in vivo, we have disrupted the GFAP gene in mice via targeted mutation in embryonic stem cells. Mice lacking GFAP developed normally, reached adulthood and reproduced. We did not find any abnormalities in the histological architecture of the CNS, in their behavior, motility, memory, blood-brain barrier function, myenteric plexi histology or intestinal peristaltic movement. Comparisons between GFAP and S-100 immunohistochemical staining patterns in the hippocampus of wild-type and mutant mice suggested a normal abundance of astrocytes in GFAP-negative mice, however, in contrast to wild-types, GFAP-negative astrocytes of the hippocampus and in the white matter of the spinal cord were completely lacking intermediate filaments. This shows that the loss of GFAP intermediate filaments is not compensated for by the up-regulation of other intermediate filament proteins, such as vimentin. The GFAP-negative mice displayed post-traumatic reactive gliosis, which suggests that GFAP up-regulation, a hallmark of reactive gliosis, is not an obligatory requirement for this process.

Automated correction of linear deformation due to sectioning in serial micrographs.

This paper describes an objective and automatic method for detection and correction of sectioning deformations in digitized micrographs, as well as an evaluation of the method applied to light and electron microscopic images of semi-thin and ultra-thin serial sections from brain cortex. The detection is based on matching of image subregions and the deformation model is bi-linear, i.e. two first-order polynomials are used for modelling compression/expansion in perpendicular directions. The procedure is applicable to prealigned serial two-dimensional sections and is primarily aimed at three-dimensional reconstruction of tissue samples consisting of a large number of cells with random distribution and morphology.