Die postnatale Entwicklung der Gliadeckschicht der Sehrinde der Katze

The astroglial cell that guides nerve fibers from growth cone to synapse in organotypic cultures of the fetal mouse spinal cord

We present electron microscopic and autoradiographic studies done using organotypic cultures of spinal cord explants excised from 15 days of gestation mouse embryos. Nerve fibers growing from the spinal cord explant carry at their tips immature mitotic astrocytic cells that lead their growth cones. These glial cells divide only during the active phase of neuronal growth, and correspond ultrastructurally to radial glia. They provide a specific cellular substrate for neuronal growth. Some growth cones form axoglial synapses with smooth membranes of immature glial cells. In contrast, maturing glial cells sprout cytoplasmic processes that tightly wrap individual growth cones and effectively arrest their growth. Next, the processes gather nerve endings into islets and nerve fibers into bundles. After internalizing nerve endings, the glial processes withdraw, bringing the endings into contact with each other. The direct neuronal appositions lead to the transformation of growth cones into presynaptic endings, signaled by their collection of presynaptic vesicles. Clustering of the vesicles at presynaptic axoglial or axodendritic membranes indicates the onset of synaptogenesis-completed by differentiation of spinous and compound synapses. Concomitant with the progress of synaptogenesis, astrocytic investment within the neuropil progressively diminishes. The differentiating astrocytic processes show secretory and tethering activity toward nerve fibers and their endings. Our observations demonstrate that astroglial cells-depending on their developmental stage-first promote and then arrest neuronal growth, and induce synaptogenesis. Thus, at any time, the growing nerve fibers are not only supported but also controlled by the astroglial cells.

Subpial glial limiting membrane of the cat spinal cord visualized by scanning electron microscopy

The subpial glial limiting membrane of the cat spinal cord was examined by scanning electron microscopy after disruption of plasma membranes of astrocytes composing this membrane by controlling the fixation time in glutaraldehyde and OsO4. The subpial glial limiting membrane of the spinal cord was principally composed of two layers of astrocytic processes: an upper layer mainly composed of laminated flattened processes and a lower layer mainly composed of thin, cord-like processes. The outermost surface of the limiting membrane immediately beneath the subpial basement membrane was totally lined with flattened, overlapping astrocytic processes. The majority of the flattened processes in the upper layer of the limiting membrane were varied in shape and usually smaller than 5 x 5 microns2 and the rest of the flattened processes were oval or round, and larger (5-10 microns in diameter) than the majority of the flattened processes. Glomerular structures of tightly packed glial filaments were observed within the superficial flattened processes. These glomerular structures appeared to occupy the central space as a cytoskeletal core. The thin, cord-like processes contained a varying number of glial filaments running parallel to one another to form narrow bundles of filaments. These bundles of filaments coursed obliquely toward the outer surface of the spinal cord where they were transformed into superficial flattened glomerular structures of various forms.

Ultrastructure of cerebellar capillary hemangioblastoma. VI. Concentric lamellar bodies of endoplasmic reticulum in stromal cells

Concentric lamellar bodies of endoplasmic reticulum (CLB) were found in the stromal cells of all five cases of cerebellar capillary hemangioblastoma studied ultrastructurally. CLB were often present in the stromal cells with voluminous loose cytoplasm, particularly those close to the capillaries. They were rarely seen in small stromal cells with abundant organelles and stromal cells distended by large lipid droplets. Small lipid droplets were usually present in the center or in the vicinity of CLB. Vesiculation and vacuolization of the lamellar arrays of CLB were common. Some vacuolized CLB were transformed into large, varying-shaped, multilocular bodies. Some stromal cells were markedly distended by numerous large vacuoles derived from CLB. Granulo-fibrillary material was frequently present in the vacuolized lamellae. Discharge of vacuoles into the interstitial space was observed. It is suggested that CLB is one of the characteristic ultrastructural features of the stromal cells. They may represent a special type of hyperplasia of the endoplasmic reticulum, but their functional significance is not known.

Production of myelin by neoplastic cells

Formation of myelin sheaths by neoplastic cells was found in a spinal ganglioneuroma. All phases of initial myelination were observed including the formation of a mesaxonal spiral and the fusion of its lamellae into a major dense line. A unique aspect of neoplastic myelin formation was the formation of sheaths around bundles of extracellular fibrils rather than axons or cell processes. Formation of myelin sheaths around extracellular material has never been observed before. The findings have implications on the mechanisms controlling initial myelination.

The development of synapses in the visual system of the cat

Synapses have been counted by electron microscopy and neurones by light microscopy through the depth of the visual cortex in a series of cats from 37 days gestation to adulthood. A few definite synapses are present as early as three weeks before birth, but there is then a latent period of four weeks before synapses increase rapidly in number 8-37 days after birth. The synapses occur just above and just below the cell plate at first, but in the adult cat they become evenly distributed in the depth of the cortex. The gradual separation of neurones by neuropil during development precedes a parallel increase in the density of synapses by about one week. The average number of synapses associated with one neurone rises to a peak of about 13,000 at seven weeks after birth. The densities of synapses and of neurones subsequently fall to slightly lower values in adult cats as the glial cells continue to develop. The timing of synaptic development in the visual cortex has been compared quantitatively with that in the L. G. N. and qualitatively with synaptogenesis in the retina. Synapses develop in the L. G. N. and cortex in a parallel fashion, and the L. G. N. precedes the cortex by a short interval of about two days. In the cell plate of the retina a few receptor synapses are present nine days before birth. Inner plexiform synapses are aslo present at this time, but ribbon-containing synapses do not appear until birth. Very few receptors possess outer segments with discs at birth, but five days later disc-bearing outer segments have developed. Thus synaptic development starts before afferent impulses can enter the visual system, but the main increase in synapses in the L. G. N. and cortex takes place four weeks after the start of synapse formation while the visual system is being used.