Periaxin expression in myelinating Schwann cells: modulation by axon-glial interactions and polarized localization during development

Development ◽  
1995 ◽  
Vol 121 (12) ◽  
pp. 4265-4273 ◽  
Author(s):  
S.S. Scherer ◽  
Y.T. Xu ◽  
P.G. Bannerman ◽  
D.L. Sherman ◽  
P.J. Brophy
Keyword(s):  
Cell Membrane ◽  
Membrane Protein ◽  
Schwann Cell ◽  
Schwann Cells ◽  
Protein Interactions ◽  
Myelin Sheath ◽  
Myelin Proteins ◽  
Developmentally Regulated ◽  
Protein Levels ◽  
Myelin Sheaths

Periaxin is a newly described protein that is expressed exclusively by myelinating Schwann cells. In developing nerves, periaxin is first detected as Schwann cells ensheathe axons, prior to the appearance of the proteins that characterize the myelin sheath. Periaxin is initially concentrated in the adaxonal membrane (apposing the axon) but, during development, as myelin sheaths mature, periaxin becomes predominately localized at the abaxonal Schwann cell membrane (apposing the basal lamina). In permanently axotomized adult nerves, periaxin is lost from the abaxonal and adaxonal membranes, becomes associated with degenerating myelin sheaths and is phagocytosed by macrophages. In crushed nerves, in which axons regenerate and are remyelinated, periaxin is first detected in the adoxonal membrane as Schwann cells ensheathe regenerating axons, but again prior to the appearance of other myelin proteins. Periaxin mRNA and protein levels change in parallel with those of other myelin-related genes after permanent axotomy and crush. These data demonstrate that periaxin is expressed by myelinating Schwann cells in a dynamic, developmentally regulated manner. The shift in localization of periaxin in the Schwann cell after completion of the spiralization phase of myelination suggests that periaxin participates in membrane-protein interactions that are required to stabilize the mature myelin sheath.

Schwann Cell Reactions in Acute and Chronic Segmental Demyelinating Neuropathies

1968 ◽  
Vol 26 ◽  
pp. 108-109
Author(s):  
Roy O. Weller
Keyword(s):  
Schwann Cell ◽  
Peripheral Nerve ◽  
Schwann Cells ◽  
Myelin Sheath ◽  
Wallerian Degeneration ◽  
Demyelinating Disease ◽  
Segmental Demyelination ◽  
Recovery Stage ◽  
Myelin Sheaths ◽  
Demyelinating Neuropathies

The length of axon that each Schwann cell myelinates in a normal peripheral nerve is approximately proportional to the diameter of the axon and the thickness of the myelin sheath produced. When segmental demyelination occurs, individual segments, represented by the length of axon covered by one Schwann cell, lose their myelin sheaths but the axons are preserved. This differs from Wallerian degeneration where myelin destruction occurs along the length of a nerve fibre following death of the axon.In experimental diphtheritic neuropathy, an acute segmental demyelinating disease, lysosomes accumulate within the Schwann cells prior to disruption of the myelin sheath; furthermore, the site of initial myelin breakdown appears to be closely related to the collections of lysosomes. The Schwann cell starts to form a new myelin sheath around the axon probably within a few hours of the destruction of the original myelin sheath, and while the latter is being catabolised within lysosomal vacuoles This stage of remyelination follows a similar course to primary myelination, so that the recovery stage is characterised by normal axons with either no myelin, or surrounded by sheaths that are very thin relative to the diameter of the axon.

The Fine Structure and Morphological Organization of the Peripheral Nerve-fibres and Trunks of the Cockroach (Periplaneta americana)

1958 ◽  
Vol s3-99 (47) ◽  
pp. 333-340
Author(s):  
ARTHUR HESS
Keyword(s):  
Cell Membrane ◽  
Schwann Cell ◽  
Peripheral Nerve ◽  
Schwann Cells ◽  
Myelin Sheath ◽  
Plasma Membranes ◽  
Periplaneta Americana ◽  
Nerve Trunk ◽  
Bromphenol Blue ◽  
Nerve Fibres

Sections of the peripheral nerve-trunks of the metathoracic leg of the cockroach (Periplaneta americana) were studied with the electron microscope. Paraffin sections were also prepared and stained. Protargol succeeds in staining the nerve-fibres. Osmium tetroxide, a modified Weigert procedure, and Luxol fast blue stain the myelin sheaths, as does mercuric bromphenol blue, a protein stain. The axoplasm is relatively free of formed elements; it contains mitochondria. The myelin sheath, when present on the largest and also some smaller fibres, consists of about two or three loose over lapping processes of Schwann cells, covered by their plasma membranes, enclosing lipid-like droplets and having a beaded appearance. Between the nerve-fibres in the nerve-trunk is Schwann-cell cytoplasm, which arises from Schwann cells that surround the whole nerve-trunk. The same fold of Schwann-cell membrane may enter into the formation of the myelin sheath around more than one nerve-fibre. Several small non-myelinated fibres, which may be as small as 0.3 µ in diameter or less, may be enclosed in the same fold of Schwann-cell membrane. Outside of the Schwann-cell layer and surrounding the nerve-trunk is a thin layer of connective tissue, which does not send trabeculae into the interior of the nerve. Tracheae and tracheoles accompany the nerve but are not included within the sheaths surrounding a nerve-trunk, even near the termination of the nerve-fibres in muscle. The structure of the cockroach peripheral nerve is compared with that described by previous investigators, with that of other insects, and with invertebrate and vertebrate nerve.

scholarly journals Grayanotoxin, veratrine, and tetrodotoxin-sensitive sodium pathways in the Schwann cell membrane of squid nerve fibers.

1976 ◽  
Vol 67 (3) ◽  
pp. 369-380 ◽  
Author(s):  
J Villegas ◽  
C Sevcik ◽  
F V Barnola ◽  
R Villegas
Keyword(s):  
Membrane Potential ◽  
Cell Membrane ◽  
Schwann Cell ◽  
Nerve Fiber ◽  
Schwann Cells ◽  
Giant Axon ◽  
Nerve Fibers ◽  
Resting Membrane Potential ◽  
External Application ◽  
Axon Membrane

The actions of grayanotoxin I, veratrine, and tetrodotoxin on the membrane potential of the Schwann cell were studied in the giant nerve fiber of the squid Sepioteuthis sepioidea. Schwann cells of intact nerve fibers and Schwann cells attached to axons cut lengthwise over several millimeters were utilized. The axon membrane potential in the intact nerve fibers was also monitored. The effects of grayanotoxin I and veratrine on the membrane potential of the Schwann cell were found to be similar to those they produce on the resting membrane potential of the giant axon. Thus, grayanotoxin I (1-30 muM) and veratrine (5-50 mug-jl-1), externally applied to the intact nerve fiber or to axon-free nerve fiber sheaths, produce a Schwann cell depolarization which can be reversed by decreasing the external sodium concentration or by external application of tetrodotoxin. The magnitude of these membrane potential changes is related to the concentrations of the drugs in the external medium. These results indicate the existence of sodium pathways in the electrically unexcitable Schwann cell membrane of S. sepioidea, which can be opened up by grayanotoxin I and veratrine, and afterwards are blocked by tetrodotoxin. The sodium pathways of the Schwann cell membrane appear to be different from those of the axolemma which show a voltage-dependent conductance.

scholarly journals Myelin sheath survival after guanethidine-induced axonal degeneration.

1992 ◽  
Vol 116 (2) ◽  
pp. 395-403 ◽  
Author(s):  
G J Kidd ◽  
J W Heath ◽  
B D Trapp ◽  
P R Dunkley
Keyword(s):  
Schwann Cells ◽  
Superior Cervical Ganglion ◽  
Myelin Sheath ◽  
Axonal Regeneration ◽  
Wallerian Degeneration ◽  
Axonal Degeneration ◽  
Serial Sections ◽  
Myelin Sheaths ◽  
Cervical Ganglion ◽  
Contrast Analysis

Membrane-membrane interactions between axons and Schwann cells are required for initial myelin formation in the peripheral nervous system. However, recent studies of double myelination in sympathetic nerve have indicated that myelin sheaths continue to exist after complete loss of axonal contact (Kidd, G. J., and J. W. Heath. 1988. J. Neurocytol. 17:245-261). This suggests that myelin maintenance may be regulated either by diffusible axonal factors or by nonaxonal mechanisms. To test these hypotheses, axons involved in double myelination in the rat superior cervical ganglion were destroyed by chronic guanethidine treatment. Guanethidine-induced sympathectomy resulted in a Wallerian-like pattern of myelin degeneration within 10 d. In doubly myelinated configurations the axon, inner myelin sheath (which lies in contact with the axon), and approximately 75% of outer myelin sheaths broke down by this time. Degenerating outer sheaths were not found at later periods. It is probably that outer sheaths that degenerated were only partially displaced from the axon at the commencement of guanethidine treatment. In contrast, analysis of serial sections showed that completely displaced outer internodes remained ultrastructurally intact. These internodes survived degeneration of the axon and inner sheath, and during the later time points (2-6 wk) they enclosed only connective tissue elements and reorganized Schwann cells/processes. Axonal regeneration was not observed within surviving outer internodes. We therefore conclude that myelin maintenance in the superior cervical ganglion is not dependent on direct axonal contact or diffusible axonal factors. In addition, physical association of Schwann cells with the degenerating axon may be an important factor in precipitating myelin breakdown during Wallerian degeneration.

scholarly journals The packing density of a supramolecular membrane protein cluster is controlled by cytoplasmic interactions

eLife ◽  
2017 ◽  
Vol 6 ◽  
Author(s):  
Elisa Merklinger ◽  
Jan-Gero Schloetel ◽  
Pascal Weber ◽  
Helena Batoulis ◽  
Sarah Holz ◽  
...  
Keyword(s):  
Cell Membrane ◽  
Membrane Protein ◽  
Protein Interactions ◽  
Cluster Size ◽  
Protein Domain ◽  
Self Organization ◽  
Cytoplasmic Protein ◽  
Transmembrane Segment ◽  
Protein Clustering ◽  
Membrane Protein Clustering

Molecule clustering is an important mechanism underlying cellular self-organization. In the cell membrane, a variety of fundamentally different mechanisms drive membrane protein clustering into nanometre-sized assemblies. To date, it is unknown whether this clustering process can be dissected into steps differentially regulated by independent mechanisms. Using clustered syntaxin molecules as an example, we study the influence of a cytoplasmic protein domain on the clustering behaviour. Analysing protein mobility, cluster size and accessibility to myc-epitopes we show that forces acting on the transmembrane segment produce loose clusters, while cytoplasmic protein interactions mediate a tightly packed state. We conclude that the data identify a hierarchy in membrane protein clustering likely being a paradigm for many cellular self-organization processes.

The fine structure and morphological organization of non-myelinated nerve fibres

1956 ◽  
Vol 144 (917) ◽  
pp. 496-506 ◽  
Keyword(s):  
Fine Structure ◽  
Schwann Cell ◽  
Peripheral Nerve ◽  
Schwann Cells ◽  
Myelin Sheath ◽  
Peripheral Nerves ◽  
Nerve Fibres ◽  
Myelinated Nerve ◽  
Morphological Organization ◽  
Myelinated Fibres

The fine structure and morphological organization of non-myelinated nerve fibres were studied by ultra-thin sectioning and electron microscopy in peripheral nerves, autonomic nerves and dorsal roots. Several non-myelinated fibres share the cytoplasm of a Schwann cell. The Schwann cells of non-myelinated fibres form a syncytium. The fibres are incompletely sur­rounded by Schwann cell cytoplasm and are suspended in the cytoplasm by mesaxons formed by the plasma membranes of the Schwann cell. The various relationships of mesaxon and nerve fibre are described. Non-myelinated fibres which do not share a Schwann cell are seen very frequently in the sciatic nerve of a new-born mouse but become less common as myelination proceeds and are rare in adults. It is therefore suggested that in developing peripheral nerves, the non­ myelinated fibres that are destined to myelinate are not organized into groups within a single Schwann cell, even before their myelin sheath has appeared; they are, at least for the ages examined here, individuals in relation to a surrounding individual Schwann cell. It is also suggested that the non-myelinated fibres that will never acquire a myelin sheath are organized in a developing peripheral nerve in the same manner as in the adult nerve—several fibres sharing a single Schwann cell that is part of a syncytial system of Schwann cells. Thus, in a developing peripheral nerve, it appears that two types of non-myelinated fibres are present—one destined to myelinate and lying alone in its own Schwann cell and the other, destined to remain unmyelinated and sharing, along with other non-myelinated fibres of the same type, a Schwann cell. The significance of these observations is discussed in relation to the development of nerve fibres and possible physiological importance.

scholarly journals Immunocytochemical localization of P0 protein in Golgi complex membranes and myelin of developing rat Schwann cells.

1981 ◽  
Vol 90 (1) ◽  
pp. 1-6 ◽  
Author(s):  
B D Trapp ◽  
Y Itoyama ◽  
N H Sternberger ◽  
R H Quarles ◽  
H Webster
Keyword(s):  
Schwann Cell ◽  
Schwann Cells ◽  
Golgi Complex ◽  
Cell Cytoplasm ◽  
Adult Rats ◽  
Thin Sections ◽  
Myelin Sheaths ◽  
Transmission Electron ◽  
P0 Protein ◽  
Developing Rat

P0 protein, the dominant protein in peripheral nervous system myelin, was studied immunocytochemically in both developing and mature Schwann cells. Trigeminal and sciatic nerves from newborn, 7-d, and adult rats were processed for transmission electron microscopy. Alternating 1-micrometer-thick Epon sections were stained with paraphenylenediamine (PD) or with P0 antiserum according to the peroxidase-antiperoxidase method. To localize P0 in Schwann cell cytoplasm and myelin membranes, the distribution of immunostaining observed in 1-micrometer sections was mapped on electron micrographs of identical areas found in adjacent thin sections. The first P0 staining was observed around axons and/or in cytoplasm of Schwann cells that had established a 1:1 relationship with axons. In newborn nerves, staining of newly formed myelin sheaths was detected more readily with P0 antiserum than with PD. Myelin sheaths with as few as three lamellae could be identified with the light microscope. Very thin sheaths often stained less intensely and part of their circumference frequently was unstained. Schmidt-Lanterman clefts found in more mature sheaths also were unstained. As myelination progressed, intensely stained myelin rings became much more numerous and, in adult nerves, all sheaths were intensely and uniformly stained. Particulate P0 staining also was observed in juxtanuclear areas of Schwann cell cytoplasm. It was most prominent during development, then decreased, but still was detected in adult nerves. The cytoplasmic areas stained by P0 antiserum were rich in Golgi complex membranes.

scholarly journals Understanding the mechanisms of entrapment neuropathies

2009 ◽  
Vol 26 (2) ◽  
pp. E7 ◽  
Author(s):  
Khoa Pham ◽  
Ranjan Gupta
Keyword(s):  
Schwann Cell ◽  
Schwann Cells ◽  
Axonal Injury ◽  
Reciprocal Relationship ◽  
Nerve Compression ◽  
Nerve Tissue ◽  
Myelin Proteins ◽  
Mechanical Stimuli ◽  
Entrapment Neuropathies ◽  
Chronic Nerve Compression

Compression neuropathies are highly prevalent, debilitating conditions with variable functional recovery following surgical decompression. Due to the limited amount of human nerve tissue available for analysis, a number of animal models have been created to help investigators understand the molecular and cellular pathogenesis of chronic nerve compression (CNC) injury. Evidence suggests that CNC injury induces concurrent Schwann cell proliferation and apoptosis in the early stages of the disorder. These proliferating Schwann cells downregulate myelin proteins, leading to local demyelination and remyelination in the region of injury. In addition, the downregulation of myelin proteins, in particular myelin-associated glycoprotein, allows for axonal sprouting. Interestingly, these changes occur in the absence of both morphological and electrophysiological evidence of axonal damage. This is in direct contrast to acute injuries, such as transection or crush, which are characterized by axonal injury followed by Wallerian degeneration. Because the accepted trigger for Schwann cell dedifferentiation is axonal injury, an alternate mechanism for Schwann response must exist in CNC injury. In vitro studies of pure Schwann cells have shown that these cells can respond directly to mechanical stimuli by downregulating myelin proteins and proliferating. These studies suggest that although the reciprocal relationship between neurons and glial cells is maintained, chronic nerve compression injury is a Schwann cell-mediated disease.

Axons regulate Schwann cell expression of the major myelin and NGF receptor genes

Development ◽  
1988 ◽  
Vol 102 (3) ◽  
pp. 499-504 ◽  
Author(s):  
G. Lemke ◽  
M. Chao
Keyword(s):  
Schwann Cell ◽  
Schwann Cells ◽  
Growth Factor Receptor ◽  
Myelin Proteins ◽  
Ngf Receptor ◽  
Genes Encoding ◽  
Messenger System ◽  
High Level ◽  
Cell Expression ◽  
Inductive Signal

The elaboration of myelin by Schwann cells is triggered by contact with appropriate peripheral axons. Among the most prominent features of this interaction is the activation and high-level expression of the genes encoding the major myelin proteins P0 and Myelin Basic Protein (MBP). Although the initial induction of these genes is thought to be dependent upon contact with axons, neither the inductive signal of the axon nor the receptor and associated second messenger system of the Schwann cell that transduces this signal has been identified. In this report, we demonstrate that expression of the P0 and MBP genes in rapidly myelinating Schwann cells is sharply reduced upon withdrawal of axons, but that this expression can be substantially restored by agents that raise the intracellular concentration of cyclic AMP. We further show that Schwann cell expression of a third gene, i.e. that encoding the Nerve Growth Factor receptor, is strongly activated by the withdrawal of axons, and that this activation is largely independent of cAMP.

scholarly journals Axon-dependent expression of YAP/TAZ mediates Schwann cell remyelination but not proliferation after nerve injury

2019 ◽  
Author(s):  
Matthew Grove ◽  
Hyunkyoung Lee ◽  
Huaqing Zhao ◽  
Young-Jin Son
Keyword(s):  
Schwann Cell ◽  
Peripheral Nerve ◽  
Schwann Cells ◽  
Nerve Injury ◽  
Myelin Sheath ◽  
Transcriptional Activity ◽  
Axon Degeneration ◽  
Adult Mice ◽  
Functional Regeneration ◽  
Growth Promoting

ABSTRACTPreviously we showed that YAP/TAZ promote not only proliferation but also differentiation of immature Schwann cells (SCs), thereby forming and maintaining the myelin sheath around peripheral axons (Grove et al., 2017). Here we show that YAP/TAZ are required for mature SCs to restore peripheral myelination, but not to proliferate, after nerve injury. We find that YAP/TAZ dramatically disappear from SCs of adult mice concurrent with axon degeneration after nerve injury. They reappear in SCs only if axons regenerate. YAP/TAZ ablation does not impair SC proliferation or transdifferentiation into growth promoting repair SCs. SCs lacking YAP/TAZ, however, fail to upregulate myelin-associated genes and completely fail to remyelinate regenerated axons. We also show that both YAP and TAZ are redundantly required for optimal remyelination. These findings suggest that axons regulate transcriptional activity of YAP/TAZ in adult SCs and that YAP/TAZ are essential for functional regeneration of peripheral nerve.

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