Summary
The neurofilamentous network of the normal rabbit brain (lateral vestibular nucleus) and of biopsies of human patients (cerebral cortex, sural nerve) was investigated electron microscopically. Thin sections of samples prepared by standard techniques and unfixed spreads of freshly isolated perikarya were utilized.
The neurofilaments are assembled into a three-dimensional network associated with the axolemma, microtubules, mitochondria and polyribosomes. The elements of this network demonstrate helicity at several levels of organization. It is proposed that they are in a dynamic state of equilibrium between ordered lattice and open network paracrystalline states. Reversible phase transitions in the subunit proteins of the neurofilaments may lead to coiling and uncoiling of the filaments and induce alterations in the network structure of the neuroplasm. Giant axonal swellings in biopsies of the sural nerve are interpreted as accumulations of cytoskeletal elements in the absence of the orienting effect of microtubules. In cortical neurons of patients with Alzheimer's disease parts of the neurofilamentous network are in altered paracrystalline states; virus-like particles occur within this modified network.
These concepts of cytoskeletal organization — network, helicity, phase transitions, and paracrystallinity — are useful for the interpretation of pathological alterations of the cytoskeleton and for an understanding of cytoskeletal organization in general.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Asbury AK, Johnson PC (1978) Bennington JL (ed) Pathology of peripheral nerve. WB Saunders Co, Toronto, Major Problems in Pathology Series, Vol 9
Asbury AK, Gale MK, Cox SC, Baringer JR, Berg BO (1972) Giant axonal neuropathy — a unique case with segmental neurofilamentous masses. Acta Neuropathol (Berl) 20:237–247
Atwood HL, Jahromi SS (1978) Fast-axon synapses of a crab leg muscle. J Neurobiol 9:1–15
Berthold CH (1978) Morphology of normal peripheral axons. In: Waxman SG (ed) Physiology and Pathobiology of Axons. Raven Press, New York, pp 3–63
Bok ST (1928) Das Rückenmark. In: Möllendorff W v (ed) Handbuch der mikroskopischen Anatomie des Menschen. Springer-Verlag, Berlin, Vol IV, Part I, p 486
Brown GH, Wolken JJ (1979) Liquid Crystals and Biological Structures. Academic Press, New York
Burton PR, Fernandez HL (1973) Delineation by lanthanum staining of filamentous elements associated with the surfaces of axonal microtubules. J Cell Sci 12:567–583
Burton PR, Hinkley RE (1974) Further electron microscopic characterization of axoplasmic microtubules of the ventral nerve cord of the crayfish. J Submicr Cytol 6:311–326
Cajal SR (1968) May RM (ed) Degeneration and regeneration of the nervous system. Hafner Publishing Co, New York, Volumes I & II
Clarke E, Beam JG (1972) The spiral nerve bands of Fontana. Brain 95:1–20
Conklin EG (1903) The cause of inverse symmetry. Anat Anz Aufsätze 23:577–588
Conklin EG (1917) Effects of centrifugal force on the structure and development of the eggs of Crepidula. J Exp Zool 22:311–373
Day WA, Gilbert DS (1972) X-ray diffraction pattern of axoplasm. Biochim Biophys Acta 285:503–506
DeBoni U, Crapper DR (1978) Paired helical filaments of the Alzheimer type in cultured neurones. Nature 271:566–568
Fernandez HL, Burton PR, Samson FE (1971) Axoplasmic transport in the crayfish nerve cord. J Cell Biol 51:176–192
Flory PF (1956) Role of crystallization in polymers and proteins. Science 124:53–60
Gilbert DS (1972) Helical Structure of Myxicola Axoplasm. Nature New Biol 237:195–198
Gilbert DS (1975) Axoplasm architecture and physical properties as seen in the Myxicola giant axon. J Physiol 253:257–301
Harrington WF (1971) A mechanochemical mechanism for muscle contraction. Proc Natl Acad Sci USA 68:685–689
Harrington WF (1979) On the origin of the contractile force in skeletal muscle. Proc Natl Acad Sci USA 76:5066–5070
Heacock AM, Agranoff BW (1977) Clockwise growth of neurites from retinal explants. Science 198:64–66
Hodge AJ, Adelman WJ Jr (1980) The neuroplasmic network in Loligo and Hermissenda neurons. J Ultrastruct Res 70:220–241
Kidd M (1964) Alzheimer's disease — an electron microscopical study. Brain 87:307–320
Kim H, Binder LI, Rosenbaum J (1979) The periodic association of MAP2 with brain microtubules in vitro. J Cell Biol 80:266–276
Koch T, Schultz P, Williams R, Lampert P (1977) Giant axonal neuropathy: a childhood disorder of microfilaments. Ann Neurol 1:438–451
Krishnan N, Kaiserman-Abramof I, Lasek RJ (1979) Helical substructure of neurofilaments isolated from Myxicola and squid giant axons. J Cell Biol 82:323–335
Kurtz SM (1961) A new method for embedding tissues in Vestopal W. J Ultrastruct Res 5:468–469
Lasek RJ (1980) The dynamic ordering of neuronal cytoskeletons. In: Lasek RJ, Shelanski M (eds) The cytoskeleton and the architecture of nervous system. Neurosci Res Program Bull. The MIT Press, Massachusetts Institute of Technology, Cambridge, Massachusetts (in press)
LeBeux YJ (1973) An ultrastructural study of the synaptic densities, nematosomes, neurotubules, neurofilaments and of a further three-dimensional filamentous network as disclosed by the E-PTA staining procedure. Z Zellforsch 143:239–272
LeBeux YJ, Willemot J (1975) An ultrastructural study of microfilaments in rat brain by means of heavy meromyosin labeling. I. The perikaryon, the dendrites and the axon. Cell Tissue Res 160:1–36
Lenk R, Penman S (1979) The cytoskeletal framework and poliovirus metabolism. Cell 16:289–301
Lenk R, Ransom L, Kaufmann Y, Penman S (1977) A cytoskeletal structure with associated polyribosomes obtained with HeLa cells. Cell 10:67–78
Livingston A (1978) The internal structure of axons from rat sciatic nerve. Cell Tissue Res 195:341–348
Metuzals J (1964) The relationships between the glia-satellite cell and the axon in the central myelinated fibers. In: Titlbach M (ed) Proceedings of the Third European Conference held in Prague. Publishing House of the Czechoslovak Academy of Sciences, Prague, Volume B, pp 301–302
Metuzals J (1966) Electron microscopy of neurofilaments. In: Uyeda R (ed) Proceedings of the Sixth International Congress for Electron Microscopy, Kyoto. Maruzen Co, Ltd, Tokyo 2:459
Metuzals J (1969) Configuration of a filamentous network in the axoplasm of the squid (Loligo pealei (L)) giant nerve fiber. J Cell Biol 43:480–505
Metuzals J, Izzard CS (1969) Spatial patterns of threadlike elements in the axoplasm of the giant nerve fiber of the squid (Loligo pealei (L)) as disclosed by differential interference microscopy and by electron microscopy. J Cell Biol 43:456–479
Metuzals J, Mushynski WE (1974) Electron microscope and experimental investigations of the neurofilamentous network in Deiters' neurons. J Cell Biol 61:701–722
Metuzals J, Tasaki I (1978) Subaxolemmal filamentous network in the giant nerve fiber of the squid (Loligo pealei (L)) and its possible role in excitability. J Cell Biol 78:597–621
Metuzals J, Lasek RJ, Hodge AJ (1980a) Stereo electron microscopy of the neurofilamentous network prepared by a sandwich technique. The Second International Congress on Cell Biology, Berlin (abstr). European J Cell Biol 22:380
Metuzals J, Hodge AJ, Lasek RJ (1980b) Neurofilament lattices in squid giant axon: stereographic study of sections and critical point dried material. (Submitted for publication)
Metuzals J, Terakawa S, Tasaki I (1980c) The axolemma-ectoplasm complex investigated in desheathed squid giant axons. Electron Microscopy 1980. Volume 2. Biology. Publ by the Seventh European Congress on Electron Microscopy Foundation, Leiden, The Netherlands
Mollenhauer HH (1964) Plastic embedding mixtures for use in electron microscopy. Stain Technol 39:111–114
Morris JH, Hudson AR, Weddell G (1972a) A study of degeneration and regeneration in the divided rat sciatic nerve based on electron microscopy. I. The traumatic degeneration of myelin in the proximal stump of the divided nerve. Z Zellforsch Mikroskop Anat 124:76–102
Morris JH, Hudson AR, Weddell G (1972b) A study of degeneration and regeneration in the divided rat sciatic nerve based on electron microscopy. II. The development of the “regenerating unit”. Z Zellforsch Mikroskop Anat 124:103–130
Needham J (1968) Order and life. The MIT Press, Massachusetts Institute of Technology, Cambridge, Massachusetts
Ochs RL (1979) Ultrastructural and biochemical characterization of crayfish nerve cord axoplasm. PhD Thesis, University of Kansas
Pant HC, Shecket G, Gainer H, Lasek RJ (1978) Neurofilament protein is phosphorylated in the squid giant axon. J Cell Biol 78:R23-R27
Pease DC (1964) Histological techniques for electron microscopy. Academic Press Inc, New York
Porter KR, Byers HR, Ellisman MH (1979) The cytoskeleton. In: Schmitt FO, Worden FG (eds) The Neurosciences, Fourth Study Program, MIT Press, Massachusetts Institute of Technology, Cambridge, Massachusetts
Renk F, Wöhlisch E (1939) Die thermoelastische Anomalie der Skelettmuskulatur und die statisch-kinetische Theorie der kautschukartigen Elastizität. Pflügers Arch 243(1): 110–125
Schaeffer AA (1920) Ameboid movement. Princeton University Press, Princeton, Chapter 12, pp 109–136
Seifriz W (1933) Twisted trees and the spiral habit. Science 77:50–51
Seifriz W (1946) Torsion in protoplasm. J Coll Sci 1:27–32
Shecket GN (1979) The phosphorylation of neurofilament protein. PhD Thesis, Case Western Reserve University (Health Sciences)
Shibayama H, Kitoh J (1978) Electron microscopic structure of the Alzheimer's neurofibrillary changes in case of atypical senile dementia. Acta Neuropathol (Berl) 41:229–234
Spencer PS, Thomas PK (1974) Ultrastructural studies of the dying-back process. II. The sequestration and removal by Schwann cells and oligodendrocytes of organelles from normal and diseased axons. J Neurocytol 3:763–783
Steinert PM (1978) Structure of the three-chain unit of the bovine epidermal keratin filament. J Mol Biol 123:49–70
Temmink JHM, Spiele H (1978) Preservation of cytoskeletal elements for electron microscopy. Cell Biol Int Rep 2:51–59
Terry RD, Gonatas NK, Weiss M (1964) Ultrastructural studies in Alzheimer's presenile dementia. Am J Pathol 44:269–297
Thomson D'Arcy W (1966) Bonner JT (ed) On growth and form. Cambridge University Press, Cambridge
Tsong TY, Karr T, Harrington WF (1979) Rapid helix-coil transitions in the S-2 region of myosin. Proc Nat Acad Sci USA 76:1109–1113
Wehner R (1976) Structure and function of the peripheral visual pathway in Hymenopterans. In: Zettler F, Weiler R (eds) Neural principles in vision. Springer-Verlag, New York, pp 280–333
Wisniewski H, Shelanski ML, Terry RD (1968) Effects of mitotic spindle inhibitors on neurotubules and neurofilaments in anterior horn cells. J Cell Biol 38:224–229
Wisniewski HM, Narang HK, Terry RD (1976) Neurofibrillary tangles of paired helical filaments. J Neurol Sci 27:173–181
Wosslosewick JJ, Porter KR (1976) Stereo high-voltage electron microscopy of whole cells of the human diploid line, WI-38. Am J Anat 147:303–324
Wolosewick JJ, Porter KR (1979) Microtrabecular lattice of the cytoplasmic ground substance. J Cell Biol 82:114–139
Wuerker RB (1970) Neurofilaments and glial filaments. Tissue Cell 2:1–9
Yamada KM, Spooner BS, Wessels NK (1971) Ultrastructure and function of growth cones and axons of cultured nerve cells. J Cell Biol 49:614–635
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Metuzals, J., Montpetit, V. & Clapin, D.F. Organization of the neurofilamentous network. Cell Tissue Res. 214, 455–482 (1981). https://doi.org/10.1007/BF00233488
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00233488