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Effects of short-term denervation on avian muscle spindle structure

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Summary

The role of the nerve in maintaining the ultrastructural integrity of avian muscle spindles was investigated by denervating the pigcon's extensor digitorum communis for periods of 10, 19, and 28 days. The equatorial region of control intrafusal fibers had a reduced density of myofilaments. Sensory endings contained mitochondria and structures resembling synaptic vesicles, and were associated with satellite cells. In the polar region, fibers had a high concentration of myofilaments; small motor endings, unlike sensory endings, lay outside of the fiber's basal lamina. The outer capsule consisted of thin, tightly layered cells which gradually became reduced in number distal to the equatorial region. In both equatorial and polar regions the capsule became more disrupted with longer denervation periods, and lysosomes and phagocytes became more abundant. The equatorial region of denervated fibers contained many myofibrils and some had peripherally-located nuclei, unlike the controls; sensory terminals were absent. The polar region of some fibers had disorganized myofilaments and others had a reduced myofilament density. Fiber diameters increased significantly in both regions. Thus, denervated intrafusal fibers lost some characteristics which distinguish them from extrafusal fibers.

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References

  • Adal MN (1969) The fine structure of the sensory region of cat muscle spindles. J Ultrastruct Res 26:332–354

    Google Scholar 

  • Adal MN (1973) The fine structure of the intrafusal muscle fibers of muscle spindles in the domestic fowl. J Anat 115:407–413

    Google Scholar 

  • Adal MN, Chew Cheng SB (1980) The sensory ending of duck muscle spindles. J Anat 131:657–668

    Google Scholar 

  • Banker BQ, Girvin JP (1972) The ultrastructural features of the normal and de-efferented mammalian muscle spindle. In: Banker BQ, Przybylski R, Van Der Meulen J, Victor M (eds) Research in muscle development and the muscle spindle. Excerpta Medica, Amsterdam, pp 267–296

    Google Scholar 

  • Barker D (1974) The avian muscle spindle. In: Hunt CC (ed) Muscle receptors. Springer, Berlin Heidelberg New York, pp 119–124

    Google Scholar 

  • Boyd IA (1962) The structure and innervation of the nuclear bag muscle fibre system and the nuclear chain muscle fibre system in mammalian muscle spindles. Proc R Soc Lond [Biol] 245:81–136

    Google Scholar 

  • Carlson BM, Hansen-Smith FM, Magon DK (1979) The life history of a free muscle graft. In: Mauro E (ed) Muscle regeneration. Raven Press, New York, pp 493–507

    Google Scholar 

  • DeReuck J, van der Eecken H, Roels H (1973) Biometrical and histochemical comparison between extra- and intra-fusal muscle fibres in denervated and re-innervated rat muscle. Acta Neuropathol (Berl) 25:17–26

    Google Scholar 

  • Hikida RS (1985) Spaced serial section analysis of the avian muscle spindle. Anat Rec 212:255–267

    Google Scholar 

  • Hikida RS, Walro JM, Miller TW (1984) Ischemic degeneration of the avian muscle spindle. Acta Neuropathol (Berl) 63:3–12

    Google Scholar 

  • Hnik P, Beranek R, Vyklicky L, Zelena J (1963) Sensory outflow from chronically tenotomized muscles. Physiol Bohemoslov 12:23–29

    Google Scholar 

  • James NT, Meek GA (1973) An electron microscopical study of avian muscle spindles. J Ultrastruct Res 43:193–204

    Google Scholar 

  • Kronmie G, Donselaar Y, Soukup T, Zelena J (1982) Development of immunohistochemical characteristics of intrafusal fibres in normal and de-efferented rat muscle spindles. Histochemistry 74:355–366

    Google Scholar 

  • Kubota K, Sato Y, Masegi T, Kobayashi M, Shishido Y (1978) Electron microscopic study of the snout muscle spindles of the mole following denervation. Anat Anz 144:81–96

    Google Scholar 

  • Kucera J (1980) Myofibrillar ATPase activity of intrafusal fibers in chronically de-afferented rat muscle spindles. Histochemistry 66:221–228

    Google Scholar 

  • Mackenson-Dean CA, Hikida RS, Frangowlakis TM (1981) Formation of muscle spindles in regenerated avian muscle grafts. Cell Tissue Res 217:37–41

    Google Scholar 

  • McArdle J, Albuquerque E (1973) A study of the reinnervation of fast and slow mammalian muscles. J Gen Physiol 61:1–23

    Google Scholar 

  • Milburn A (1973) The early development of muscle spindles in the rat. J Cell Sci 12:175–195

    Google Scholar 

  • Ovalle WK (1976) Fine structure of the avian muscle spindle capsule. Cell Tissue Res 166:283–298

    Google Scholar 

  • Ovalle WK (1978) Histochemical dichotomy of extrafusal and intrafusal fibers in avian slow muscle. Am J Anat 152:587–598

    Google Scholar 

  • Ovalle WK, Dow PR (1983) Comparative ultrastructure of the inner capsule of the muscle spindle and the tendon organ. Am J Anat 166:343–357

    Google Scholar 

  • Reichmann H, Srihari T, Pette D (1983) Ipsi- and contralateral fibre transformations by cross reinnervation. A principle of symmetry. Pflügers Arch 397:202–208

    Google Scholar 

  • Rogers SL (1982) Muscle spindle formation and differentiation in regenerating rat muscle grafts.Dev Biol 94:265–283

    Google Scholar 

  • Rogers SL, Carlson BM (1981) A quantitative assessment of muscle spindle formation in reinnervated and non-reinnervated grafts of the rat extensor digitorum longus muscle. Neuroscience 6:87–94

    Google Scholar 

  • Schiaffino S, Pierobon Bormioli S (1976) Morphogenesis of rat muscle spindles after nerve lesion during early postnatal developmênt. J Neurocytol 5:319–336

    Google Scholar 

  • Schröder JM (1974) The fine structure of de- and reinnervated muscle spindles. I. The increase, atrophy, and “hypertrophy” of intrafusal muscle fibers. Acta Neuropathol (Berl) 30:109–128

    Google Scholar 

  • Schröder JM, Kemme PT, Scholz L (1979) The fine structure of denervated and reinnervated muscle spindles: morphometric study of intrafusal muscle fibers. Acta Neuropathol (Berl) 46:95–106

    Google Scholar 

  • Tower SS (1932) Atrophy and degeneration in the muscle spindle. Brain 55:77–90

    Google Scholar 

  • Uehara Y (1978) Occurence of an “extrafusal muscle fiber” in the spindle capsule of normal adult zebra-finches: an electron microscopical study. J Electr Microsc (Tokyo) 27:293–299

    Google Scholar 

  • Von Arendt K-W, Asmussen G (1976a) Die Muskelspindeln im denervierten und reinnervierten M. soleus der Ratte. I. Veränderungen der Anzahl, der Verteilung und der Länge der Muskelspíndeln. Anat Anz 140:241–253

    Google Scholar 

  • Von Arendt K-W, Asmussen G (1976b) Die Muskelspindeln im denervierten und reinnervierten M. soleus der Ratte. II Veränderungen an den extra- und intrafusalen Muskelfasern. Anat Anz 140:254–266

    Google Scholar 

  • Werner JK (1973) Duration of normal innervation required for complete differentiation of muscle spindles in newborn rats. Exp Neurol 41:214–217

    Google Scholar 

  • Yellin H, Eldred E (1970) Spindle activity of the tenotomized gastrocnemius muscle in the cat. Exp Neurol 29:513–533

    Google Scholar 

  • Zelena J (1957) The morphogenetic influence of innervation on the ontogenetic development of muscle spindles. J Embryol Exp Morphol 5:283–292

    Google Scholar 

  • Zelena J, Soukup T (1973) Development of muscle spindles deprived of fusimotor innervation. Z Zellforsch Mikrosk Anat 144:435–452

    Google Scholar 

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Authors and Affiliations

  1. Program in Anatomy, Development and Neurobiology, Department of Zoological and Biomedical Sciences, Ohio University Athens, Irvine Hall, 45701, OH, USA

    T. W. Miller & R. S. Hikida

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  1. T. W. Miller
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  2. R. S. Hikida
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Supported by NIH grant 5RO1AM26992

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Miller, T.W., Hikida, R.S. Effects of short-term denervation on avian muscle spindle structure. Acta Neuropathol 70, 127–134 (1986). https://doi.org/10.1007/BF00691430

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  • DOI: https://doi.org/10.1007/BF00691430

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