An electron microscope study of quantitative relationships between axon and Schwann cell sheath in myelinated fibres of peripheral nerves

Pannese, Ennio; Rigamonti, L; Procacci, Patrizia; Ledda, M.; Arcidiacono, G.; Frattola, D.

doi:10.1007/bf00309678

Cited by 10 publications

(5 citation statements)

References 35 publications

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“…More than 100 years ago, it was noticed that myelination is related to axon size (Donaldson and Hoke, 1905), although the morphological relationship between axons, myelin sheaths, and Schwann cells was unknown at that time. In the peripheral nervous system, axons greater than 1 lm in diameter are almost invariably myelinated, whereas those smaller than 1 lm are not (Fraher et al, 1990;Friede and Bischhausen, 1982;Pannese et al, 1987;Williams and Wendell-Smith, 1971). Myelinating Schwann cells sort axons into a oneto-one ratio and wrap one axon multiple times, while in rodents, the majority of nonmyelinating Schwann cells engulf several axons (typically sensory C-fiber axons) within a Remak bundle.…”

Section: Nrg1 and Schwann Cell Myelinationmentioning

confidence: 99%

“…More than 100 years ago, it was noticed that myelination is related to axon size (Donaldson and Hoke,1905), although the morphological relationship between axons, myelin sheaths, and Schwann cells was unknown at that time. In the peripheral nervous system, axons greater than 1 μm in diameter are almost invariably myelinated, whereas those smaller than 1 μm are not (Fraher et al,1990; Friede and Bischhausen,1982; Pannese et al,1987; Williams and Wendell‐Smith,1971). Myelinating Schwann cells sort axons into a one‐to‐one ratio and wrap one axon multiple times, while in rodents, the majority of nonmyelinating Schwann cells engulf several axons (typically sensory C‐fiber axons) within a Remak bundle.…”

Section: Nrg1 and Schwann Cell Myelinationmentioning

confidence: 99%

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Neuregulin‐1, a key axonal signal that drives Schwann cell growth and differentiation

Birchmeier¹,

Nave

2008

Glia

215

167

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Interactions between neuronal and glial cells are crucial for establishing a functional nervous system. Many aspects of Schwann cell development and physiology are regulated by neuronal signals; possibly the most spectacular is the elaboration of the myelin sheath. An extensive line of research has revealed that one neuronal factor, termed ''neuregulin'', promotes Schwann cell growth and survival, migration along the extending axon, and myelination. The versatility of glial responses elicited by this factor is thus clearly astounding. V V C

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Section: Nrg1 and Schwann Cell Myelinationmentioning

confidence: 99%

“…More than 100 years ago, it was noticed that myelination is related to axon size (Donaldson and Hoke,1905), although the morphological relationship between axons, myelin sheaths, and Schwann cells was unknown at that time. In the peripheral nervous system, axons greater than 1 μm in diameter are almost invariably myelinated, whereas those smaller than 1 μm are not (Fraher et al,1990; Friede and Bischhausen,1982; Pannese et al,1987; Williams and Wendell‐Smith,1971). Myelinating Schwann cells sort axons into a one‐to‐one ratio and wrap one axon multiple times, while in rodents, the majority of nonmyelinating Schwann cells engulf several axons (typically sensory C‐fiber axons) within a Remak bundle.…”

Section: Nrg1 and Schwann Cell Myelinationmentioning

confidence: 99%

Neuregulin‐1, a key axonal signal that drives Schwann cell growth and differentiation

Birchmeier¹,

Nave

2008

Glia

215

167

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“…In general, myelin volume is strongly correlated to both the axonal diameter (caliber) and the length of the myelinated internodal axonal segment, with only minor species-and nervespecific differences (Friede & Bischhausen, 1982;Pannese et al, 1987). In particular, the axonal caliber appears to be a critical parameter for myelination of small axons (Voyvodic, 1989).…”

Section: Can Cpcs Solve a Logistical Issue?mentioning

confidence: 99%

Biogenesis and maintenance of cytoplasmic domains in myelin of the central nervous system

Velte¹

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“…In turn, each Schwann cell will produce a single myelin segment, termed internode, along an individual axon and leaving unmyelinated small regions in between which are called nodes of Ranvier. On the other hand smaller axons (<1 µm) bundles surrounded by Schwann cell cytoplasm instead of getting myelinated they become segregated from each other through ending up in separate pockets in the same Schwann cell forming a unique PNS myelin structure called Remak Bundle [10][11][12][13][14] (Fig. 1).…”

Section: Schwann Cell Origin and Developmentmentioning

confidence: 99%

Schwann cell differentiation in Charcot-Marie-Tooth disease 1 A (CMT1A)

Abdelaal¹

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Charcot-Marie-Tooth disease is the most common inherited neuropathy and a duplication of the peripheral myelin protein 22 gene (PMP22) causes the most frequent sub-form Charcot-Marie-Tooth 1A (CMT1A). In contrary to the notion that CMT1A manifests in the second decade of life, moderate walking disability and electrophysiological abnormalities are usually already present during childhood. The early onset and developmental nature of the disease is also supported by findings derived from a Pmp22 transgenic rat model for CMT1A (CMT rat), which displays a reduced number of myelinated fibers per peripheral nerve already early postnatally and never reaches a wildtype level throughout development. RNA transcription analysis has revealed that there is a striking continuous upregulation of Schwan cell neuregulin 1 type I (NRG1_I) which we could show that it is contributing to the reported hypermyelination of small caliber axons in CMT1A rodent models. On the other hand, CMT rat Schwann cells show a strongly impaired lipid biogenesis required for myelination as assessed by RNA expression and lipid profiling of peripheral nerve transcriptomes and myelin composition, respectively. Importantly, Pmp22 overexpressing Schwann cell also reflects an impaired myelination competence in vitro, when co-cultured with dorsal root ganglia neurons. A remarkable improvement of Schwann cell myelination upon supplementation with phosphatidylcholine in vitro has led to the hypothesis that exogenous supplementation with lipids in vivo may improve disease progression. Indeed, we observed improved disease progression on the histological, electrophysiological and behavioral levels in CMT rats which were fed with a chow enriched in lecithin from P2 to adulthood. Moreover, disease amelioration is also visible after late long term (P21-P112) and early short term treatment (P2 to P21), but the effect is fading after treatment cessation. Therefore, continuously supplying patients with exogenous lipids may be considered as a promising therapeutic approach for CMT1A disease. Figure 1:The Schwann cell developmental lineage and repair response. The diagram shows the main developmental cell types, repair (Bungner) Schwann cell and steps of Schwann cell development. Solid arrows indicate developmental steps. Red arrows indicate Schwann cell injury associated transformation into repair cell. Dashed arrows indicate post-repair response. E stands for embryonic time points in mouse development. (Adapted from K. R. Jessen and R. Mirsky (2016).Figure 2:Schematic structures of major NRG1 isoforms in the nervous system. Unlike type III isoform, has two transmembrane domains, other isoforms (I&II) have only one transmembrane domain. Proteolytic cleavage in the juxta-membrane area releases the epidermal growth factor (EGF) domain containing part of both I&II isoforms while III remain anchored to the membrane. Adaptaed from Jessen & Mirsky 2005.

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An electron microscope study of quantitative relationships between axon and Schwann cell sheath in myelinated fibres of peripheral nerves

Cited by 10 publications

References 35 publications

Neuregulin‐1, a key axonal signal that drives Schwann cell growth and differentiation

Neuregulin‐1, a key axonal signal that drives Schwann cell growth and differentiation

Biogenesis and maintenance of cytoplasmic domains in myelin of the central nervous system

Schwann cell differentiation in Charcot-Marie-Tooth disease 1 A (CMT1A)

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