Summary
Subpial astrocytic processes were examined in developing rats, mainly with complementary replicas, to see how orthogonal arrays of particles (OAs) are formed and become numerous in membranes covered by basal lamina. Only a few (4.2%) endfeet in the membranes contacting the basal lamina (subpial membranes) had acquired OAs by the 19-day foetal stage. The number of endfeet provided with OAs increased drastically in the prenatal period, continued to increase at birth (P0), and somewhat more slowly in the early postnatal period (P0–P3), reaching 100% at P10. There were neuronal processes as well abutting on the basal lamina at the pial surface but they were easy to distinguish from astrocytic endfeet because of their larger intramembrane particles (IMPs), which are sparsely distributed and in patch-like aggregations. The distribution density of OAs in differentiated astrocytic endfeet also increased very gradually with age until P0, a little faster in the early postnatal period, and drastically from P10 to adult. Ordinary globular IMPs increased in number with age and continued to increase in the lateral membrane where OAs were still very few, though less rapidly in the subpial membrane as OAs became numerous. With maturation, larger IMPs became conspicuous in the lateral membrane but not in the subpial, suggesting that larger IMPs were predominantly used to form OAS. We have proposed the idea that relatively large IMPs line up to form single linear arrays (SLs), appearing as grooves on the E face, and that occasionally some SLs line up in multiple rows multiple linear arrays (MLs)] and that SLs or MLs fuse with one another to become rod-like strands, then divide into squares to become OAS. SLs and MLs appeared ontogenetically earlier than OAs, and continued to appear in membranes provided with OAS. In areas where membranes were bent, transition of these three structures was observable and the proportion of OAs increased with age. Further, in such areas, alignment of OAs was different according to membrane curvature: concentric in and around protrusions, perpendicular to the edge of invaginations. This unique association of OA alignment with membrane curvature suggests that OAs contribute to some membrane stability in the area covered by the basal lamina and provide the membrane with special resistance to bending.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anders, J. J. &Brightman, M. W. (1979) Assemblies of particles in the cell membranes of developing, mature and reactive astrocytes.Journal of Neurocytology 8, 777–95.
Anders, J. J. &Brightman, M. W. (1982) Particle assemblies in astrocytic plasma membranes are rearranged by various agentsin vitro and cold injuryin vivo, Journal of Neurocytology 11, 1009–29.
Brew, H., Gray, P. T. A., Mobbs, P. &Attwell, D. (1986) Endfeet of retinal glial cells have higher densities of ion channels that mediate K+ buffering.Nature 324, 466–8.
Bridgman, P. C., Carr, C., Pedersen, S. E. &Cohen, J. B. (1987) Visualization of cytoplasmic surface ofTorpedo postsynaptic membranes by free-etch and immunoelectron microscopy,Journal of Cell Biology 105, 1829–46.
Brightman, M. W., Prescott, L. &Reese, T. S. (1975) Intercellular junctions of special ependyma. InBrain-Endocrine Interaction II. The Ventricular System (edited byKnigge, K. M., Scott, D. E., Kobayashi, H. &Ishii, S.), pp. 146–65. Basel: Karger.
Brown, D., Gluck, S. &Hartwig, J. (1987) Structure of the novel membrane-coating material in proton-secreting epithelial cells and identification as an H+ ATPase.Journal of Cell Biology 105, 1637–48.
Bullivant, S., Metcalf, P. &Warne, K. P. (1979) Fine structure of yeast plasma membrane after freeze fracturing in a simple shielded device. InFreeze Fracture: Methods, Artifacts, and Interpretations (edited byRash, J. E. &Hudson, C. S.), pp. 141–7. New York: Raven Press.
Chambard, M., Gabrion, J. &Mauchamp, J. (1981) Influence of collagen gel on the orientation of epithelial cell polarity: follicle formation from isolated thyroid cells and from preformed monolayers.Journal of Cell Biology 91, 157–66.
Dermietzel, R. (1974) Junctions in the central nervous system of the cat. III. Gap junctions and membraneassociated orthogonal particle complexes (MOPC) in astrocytic membranes.Cell and Tissue Research 149, 121–35.
Elfvin, L. G. &Forsman, C. (1978) The ultrastructure of junctions between satellite cells in mammalian sympathetic ganglia as revealed by freeze-etching.Journal of Ultrastructure Research 63, 261–74.
Fujita, S. (1980) Cytogenesis and pathology of neuroglia and microglia.Pathology Research and Practice 68, 271–8.
Gotow, T. (1984) Cytochemical characteristics of astrocytic plasma membranes specialized with numerous orthogonal arrays.Journal of Neurocytology 13, 431–48.
Gotow, T. &Hashimoto, P. H. (1984) Plasma membrane organization of astrocytes in elasmobranchs with special reference to the brain barrier system.Journal of Neurocytology 13, 727–42.
Gotow, T., Yoshikawa, H. &Hashimoto, P. H. (1985) Distribution patterns of orthogonal arrays and alkaline phosphatase in plasma membranes of satellite cells in rat spinal ganglia.Anatomy and Embryology 171, 171–9.
Gotow, T. &Hashimoto, P. H. (1988) Deep-etch structure of astrocytes at the superficial glia limitans, with special emphasis on the internal and external organization of their plasma membranes.Journal of Neurocytology 17, 399–113.
Gotow, T. &Hashimoto, P. H. (1989) Orthogonal arrays of particles in plasma membranes of Müller cells in the guinea pig retina.Glia 2, 273–85.
Hatton, J. O. &Ellisman, M. H. (1981) The distribution of orthogonal arrays and their relationship to intercellular junctions in neuroglia of the freeze-fractured hypothalamo-neurohypophysial system.Cell and Tissue Research 215, 309–23.
Heuser, J. E. &Salpeter, S. R. (1979) Organization of acetylcholine receptors in quick-frozen, deep-etched, and rotary-replicatedTorpedo postsynaptic membrane.Journal of Cell Biology 82, 150–73.
Hicks, S. P. &D'Amato, C. T. (1968) Cell migrations to the isocortex in the rat.Anatomical Record 160, 619–34.
Kimelberg, H. K. (1983) Primary astrocytic cultures — a key to astrocyte function.Cellular and Molecular Neurobiology 3, 1–16.
Landis, D. M. D. &Reese, T. S. (1974) Arrays of particles in freeze-fractured astrocytic membranes.Journal of Cell Biology 60, 316–20.
Landis, D. M. D. &Reese, T. S. (1981a) Astrocytic membrane structure: change after circulatory arrest.Journal of Cell Biology 88, 660–3.
Landis, D. M. D. &Reese, T. S. (1981b) Membrane structure in mammalian astrocytes: a review of freeze-fracture studies on adult, developing, reactive and cultured astrocytes.Journal of Experimental Biology 95, 35–48.
Landis, D. M. D. &Reese, T. S. (1982) Regional organization of astrocytic membranes in cerebellar cortex.Neuroscience 7, 937–50.
Newman, E. A. (1985) Membrane physiology of retinal glial (Müller) cells.Journal of Neuroscience 5, 2225–39.
Newman, E. A. (1986) High potassium conductance in astrocyte endfeet.Science 233, 453–4.
Newman, E. A. (1987) Distribution of potassium conductance in mammalian Müller (glial) cells: a comparative study.Journal of Neuroscience 7, 2423–32.
Newman, E. A. (1988) Potassium conductance in Müller cells of fish.Glia 1, 275–81.
Pannese, E., Luciano, L., Iurato, S. &Reale, E. (1977) Intracellular junctions and other membrane specializations in developing spinal ganglia: a freeze-fracture study,Journal of Ultrastructure Research 60, 169–80.
Pauli, B. U., Weinstein, R. S., Sohle, L. W. &Alroy, J. (1977) Freeze-fracture of monolayer cultures,Journal of Cell Biology 72, 763–9.
Peters, A. &Feldman, M. (1973) The cortical plate and molecular layer of the late rat fetus.Zeitschrift für Anatomic und Entwicklungsgeschichte 141, 3–37.
Privat, A. (1977) The ependyma and subependymal layer of the young rat: a new contribution with freeze-fracture.Neuroscience 2, 447–57.
Rakic, P. (1978) Neuronal migration and contact guidance in the primate telencephalon.Postgraduate Medical Journal 54 (Supplement I), 25–40.
Rash, J. E., Graham, W. F. &Hudson, C. S. (1979) Sources and rates of contamination in a conventional Balzers freeze-etch device. InFreeze Fracture: Methods, Artifacts, and Interpretations (edited byRash, J. E. &Hudson, C. S.), pp. 111–22. New York: Raven Press.
Raviola, G. (1977) The structural basis of the blood-ocular barriers.Experimental Eye Research Supplement 25, 27–63.
Reale, E. &Luciano, L. (1974) Introduction to freeze-fracture method in retinal research.Albrecht von Graefes Archiv für klinische und experimentelle Ophthalmologie 192, 73–87.
Ripps, H. &Witkovsky, P. (1985) Neuron-glia interaction in the brain and retina. InProgress in Retinal Research (edited byOsborne, N. N. &Chader, G. J.), pp. 181–219. Oxford: Pergamon Press.
Skoff, R. P., Price, D. L. &Stocks, A. (1976) Electronmicroscopic autoradiographic studies of gliogenesis in rat optic nerve. II. Time of origin.Journal of Comparative Neurology 169, 313–34.
Tao-Cheng, J.-H., Nagy, Z. &Brightman, M. W. (1986) Intramembranous changes in astrocytes induced by coculturing with cerebral endothelial cells.Anatomical Record 214, 131A.
Tao-Cheng, J.-H., Nagy, Z. &Brightman, M. W. (1987) Tight junctions of brain endotheliumin vitro are enhanced by astroglia.Journal of Neuroscience 7, 3293–9.
Verma, V., Schmidt, H. &Richter, H.-P. (1988) Structural alterations in the membrane of the slow muscle fiber ofRana temporaria after denervation.Journal of Ultrastructure and Molecular Structure Research 99, 27–37.
Wolburg, H. &Berg, K. (1987) Heterogeneity of Müller cell endfeet in the rabbit retina as revealed by freezefracturing.Neuroscience Letters 82, 273–7.
Wolburg, H. &Berg, K. (1988) Distribution of orthogonal arrays of particles in the Müller cell membrane of the mouse retina.Glia 1, 246–52.
Wolburg, H., Kastner, R. &Kurz-Isler, G. (1983) Lack of orthogonal particle assemblies and presence of tight junctions in astrocytes of the gold fish (Carassius auratus). A freeze-fracture study.Cell and Tissue Research 234, 389–102.
Wujek, J. R. &Reier, P. J. (1984) Astrocytic membrane morphology: differences between mammalian and amphibian astrocytes after axotomy.Journal of Comparative Neurology 222, 607–19.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Gotow, T., Hashimoto, P.H. Developmental alterations in membrane organization of rat subpial astrocytes. J Neurocytol 18, 731–747 (1989). https://doi.org/10.1007/BF01187227
Received:
Revised:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01187227