An experimental analysis of interlamellar tight junctions in amphibian and mammalian C.N.S. myelin

Claudin-11 Tight Junctions in Myelin Are a Barrier to Diffusion and Lack Strong Adhesive Properties

The radial component is a network of interlamellar tight junctions (TJs) unique to central nervous system myelin. Ablation of claudin-11, a TJ protein, results in the absence of the radial component and compromises the passive electrical properties of myelin. Although TJs are known to regulate paracellular diffusion, this barrier function has not been directly demonstrated for the radial component, and some evidence suggests that the radial component may also mediate adhesion between myelin membranes. To investigate the physical properties of claudin-11 TJs, we compared fresh, unfixed Claudin 11-null and control nerves using x-ray and neutron diffraction. In Claudin 11-null tissue, we detected no changes in myelin structure, stability, or membrane interactions, which argues against the notion that myelin TJs exhibit significant adhesive properties. Moreover, our osmotic stressing and D2O-H2O exchange experiments demonstrate that myelin lacking claudin-11 is more permeable to water and small osmolytes. Thus, our data indicate that the radial component serves primarily as a diffusion barrier and elucidate the mechanism by which TJs govern myelin function.

Tricellulin is expressed in autotypic tight junctions of peripheral myelinating Schwann cells

Autotypic tight junctions are formed by tight junction-like structures in three regions of myelinating Schwann cells, the paranodal loops, Schmidt-Lanterman incisures, and outer/inner mesaxons, and various tight junction molecules, including claudin-19 and junctional adhesion molecule (JAM)-C. Our findings demonstrate the identification and subcellular distribution of a novel tricellular tight junction protein, tricellulin (TRIC), in the autotypic tight junctions of mouse myelinating Schwann cells, compared with the autotypic adherens junction protein E-cadherin and the autotypic tight junction protein JAM-C, which are expressed in the paranodal loops, Schmidt-Lanterman incisures, and mesaxons. In real-time RT-PCR, the expression level of TRIC mRNA was about 10-fold higher in the sciatic nerve than in the spinal cord or cerebrum. In immunostaining, TRIC signals were completely restricted to the peripheral nervous system (PNS) and strongly concentrated at the paranodal loops, Schmidt-Lanterman incisures, and mesaxons of myelinating Schwann cells. In addition, TRIC was expressed in the thin region of the paranode and there was a gap between TRIC and the Na+ channel. Furthermore, TRIC was more distally located from the node than E-cadherin and was colocalized with JAM-C. It is possible that TRIC may be a component to maintain the integrity for PNS myelin function and morphology. This manuscript contains online supplemental material at http://www.jhc.org. Please visit this article online to view these materials.

Claudin Proteins And Neuronal Function

The identification and characterization of the claudin family of tight junction (TJ) proteins in the late 1990s ushered in a new era for research into the molecular and cellular biology of intercellular junctions. Since that time, TJs have been studied in the contexts of many diseases including deafness, male infertility, cancer, bacterial invasion and liver and kidney disorders. In this review, we consider the role of claudins in the nervous system focusing on the mechanisms by which TJs in glial cells are involved in neuronal function. Electrophysiological evidence suggests that claudins may operate in the central nervous system (CNS) in a manner similar to polarized epithelia. We also evaluate hypotheses that TJs are the gatekeepers of an immune-privileged myelin compartment and that TJs emerged during evolution to form major adhesive forces within the myelin sheath. Finally, we consider the implications of CNS myelin TJs in the contexts of behavioral disorders (schizophrenia) and demyelinating/hypomyelinating diseases (multiple sclerosis and the leukodystrophies), and explore evidence of a possible mechanism governing affective disorder symptoms in patients with white matter abnormalities.

Tight junctions potentiate the insulative properties of small CNS myelinated axons

Claudin family proteins form the physical barriers of tight junctions (TJs) and regulate paracellular diffusion across polarized epithelia. In addition to these heterotypic TJs, claudin 11 forms autotypic TJs comprising the radial component of central nervous system myelin. The exact function of these TJs has been unclear, although their location at the membrane perimeter is well sited to regulate diffusion between the interstitium and intramyelinic space. In this study, we demonstrate that claudin 11 affords rapid nerve conduction principally for small diameter myelinated axons. Claudin 11–null mice have preserved myelin and axonal architecture, but as much as a 60% decrease in conduction. They also have increased action potential thresholds and activated internodal potassium channels. These data indicate that TJs modulate the biophysical properties of myelin. Computational modeling reveals that claudin 11 reduces current flow through myelin and moderates its capacitive charging. Together, our data shed new light on myelin structural components and our understanding of the biology and pathophysiology of this membrane.

P0 protein is required for and can induce formation of schmidt-lantermann incisures in myelin internodes

Axons in the PNS and CNS are ensheathed by multiple layers of tightly compacted myelin membranes. A series of cytoplasmic channels connect outer and inner margins of PNS, but not CNS, myelin internodes. Membranes of these Schmidt-Lantermann (S-L) incisures contain the myelin-associated glycoprotein (MAG) but not P(0) or proteolipid protein (PLP), the structural proteins of compact PNS (P(0)) and CNS (PLP) myelin. We show here that incisures are present in MAG-null and absent from P(0)-null PNS internodes. To test the possibility that P(0) regulates incisure formation, we replaced PLP with P(0) in CNS myelin. S-L incisures formed in P(0)-CNS myelin internodes. Furthermore, axoplasm ensheathed by 65% of the CNS incisures examined by electron microscopy had focal accumulations of organelles, indicating that these CNS incisures disrupt axonal transport. These data support the hypotheses that P(0) protein is required for and can induce S-L incisures and that P(0)-induced CNS incisures can be detrimental to axonal function.

Subtle myelin defects in PLP-null mice

This study explores subtle defects in the myelin of proteolipid protein (PLP)-null mice that could potentially underlie the functional losses and axon damage known to occur in this mutant and in myelin diseases including multiple sclerosis. We have compared PLP-null central nervous system (CNS) myelin with normal myelin using ultrastructural methods designed to emphasize fine differences. In the PLP-null CNS, axons large enough to be myelinated often lack myelin entirely or are surrounded by abnormally thin sheaths. Short stretches of cytoplasm persist in many myelin lamellae. Most strikingly, compaction is incomplete in this mutant as shown by the widespread presence of patent interlamellar spaces of variable width that can be labeled with ferricyanide, acting as an aqueous extracellular tracer. In thinly myelinated fibers, interlamellar spaces are filled across the full width of the sheaths. In thick myelin sheaths, they appear filled irregularly but diffusely. These patent spaces constitute a spiral pathway through which ions and other extracellular agents may penetrate gradually, possibly contributing to the axon damage known to occur in this mutant, especially in thinly myelinated fibers, where the spiral path length is shortest and most consistently labeled. We show also that the "radial component" of myelin is distorted in the mutant ("diagonal component"), extending across the sheaths at 45 degrees instead of 90 degrees. These observations indicate a direct or indirect role for PLP in maintaining myelin compaction along the external surfaces of the lamellae and to a limited extent, along the cytoplasmic surfaces as well and also in maintaining the normal alignment of the radial component.

Tight junctions in Schwann cells of peripheral myelinated axons: a lesson from claudin-19-deficient mice

Tight junction (TJ)-like structures have been reported in Schwann cells, but their molecular composition and physiological function remain elusive. We found that claudin-19, a novel member of the claudin family (TJ adhesion molecules in epithelia), constituted these structures. Claudin-19-deficient mice were generated, and they exhibited behavioral abnormalities that could be attributed to peripheral nervous system deficits. Electrophysiological analyses showed that the claudin-19 deficiency affected the nerve conduction of peripheral myelinated fibers. Interestingly, the overall morphology of Schwann cells lacking claudin-19 expression appeared to be normal not only in the internodal region but also at the node of Ranvier, except that TJs completely disappeared, at least from the outer/inner mesaxons. These findings have indicated that, similar to epithelial cells, Schwann cells also bear claudin-based TJs, and they have also suggested that these TJs are not involved in the polarized morphogenesis but are involved in the electrophysiological "sealing" function of Schwann cells.

Distinct claudins and associated PDZ proteins form different autotypic tight junctions in myelinating Schwann cells

The apposed membranes of myelinating Schwann cells are joined by several types of junctional specializations known as autotypic or reflexive junctions. These include tight, gap, and adherens junctions, all of which are found in regions of noncompact myelin: the paranodal loops, incisures of Schmidt-Lanterman, and mesaxons. The molecular components of autotypic tight junctions have not been established. Here we report that two homologues of Discs Lost-multi PDZ domain protein (MUPP)1, and Pals-associated tight junction protein (PATJ), are differentially localized in myelinating Schwann cells and associated with different claudins. PATJ is mainly found at the paranodal loops, where it colocalized with claudin-1. MUPP1 and claudin-5 colocalized in the incisures, and the COOH-terminal region of claudin-5 interacts with MUPP1 in a PSD-95/Disc Large/zona occludens (ZO)-1 (PDZ)-dependent manner. In developing nerves, claudin-5 and MUPP1 appear together in incisures during the first postnatal week, suggesting that they coassemble during myelination. Finally, we show that the incisures also contain four other PDZ proteins that are found in epithelial tight junctions, including three membrane-associated guanylate-kinase proteins (membrane-associated guanylate-kinase inverted-2, ZO-1, and ZO-2) and the adaptor protein Par-3. The presence of these different tight junction proteins in regions of noncompact myelin may be required to maintain the intricate cytoarchitecture of myelinating Schwann cells.

CNS myelin and sertoli cell tight junction strands are absent in Osp/claudin-11 null mice

Oligodendrocyte-specific protein (OSP)/claudin-11 is a recently identified transmembrane protein found in CNS myelin and testis with unknown function. Herein we demonstrate that Osp null mice exhibit both neurological and reproductive deficits: CNS nerve conduction is slowed, hindlimb weakness is conspicuous, and males are sterile. Freeze fracture reveals that tight junction intramembranous strands are absent in CNS myelin and between Sertoli cells of mutant mice. Our results demonstrate that OSP is the mediator of parallel-array tight junction strands and distinguishes this protein from other intrinsic membrane proteins in tight junctions. These novel results provide direct evidence of the pivotal role of the claudin family in generating the paracellular physical barrier of tight junctions necessary for spermatogenesis and normal CNS function.

Claudin-11/OSP-based tight junctions of myelin sheaths in brain and Sertoli cells in testis

Members of the newly identified claudin gene family constitute tight junction (TJ) strands, which play a pivotal role in compartmentalization in multicellular organisms. We identified oligodendrocyte-specific protein (OSP) as claudin-11, a new claudin family member, due to its sequence similarity to claudins as well as its ability to form TJ strands in transfected fibroblasts. Claudin-11/OSP mRNA was expressed in the brain and testis. Immunofluorescence microscopy with anti-claudin-11/OSP polyclonal antibody (pAb) and anti-neurofilament mAb revealed that in the brain claudin-11/OSP-positive linear structures run in a gentle spiral around neurofilament-positive axons. At the electron microscopic level, these linear structures were identified as the so-called interlamellar strands in myelin sheaths of oligodendrocytes. In testis, well-developed TJ strands of Sertoli cells were specifically labeled with anti-claudin-11/OSP pAb both at immunofluorescence and electron microscopic levels. These findings indicated that the interlamellar strands of oligodendrocyte myelin sheaths can be regarded as a variant of TJ strands found in many other epithelial cells, and that these strands share a specific claudin species, claudin-11/OSP, with those in Sertoli cells to create and maintain the repeated compartments around axons by oligodendrocytes.

Myelin-associated oligodendrocytic basic protein is essential for normal arrangement of the radial component in central nervous system myelin

We previously reported that myelin-associated oligodendrocytic basic protein (MOBP) was abundantly expressed in the central nervous system (CNS) myelin, and shared several characteristics with myelin basic protein (MBP). In particular, a cluster of positively charged amino acids was considered to facilitate compaction of the cytoplasmic face of the myelin sheath, as in the case of MBP. However, the contribution of MOBP in forming and maintaining the myelin sheath still remains unclear. Recent investigations showed that one isoform of MOBP was expressed in the embryo prior to myelination, and MOBP isoforms were colocalized with the microtubular network and nucleus in vitro. To explore the role of MOBP in vivo, we generated MOBP-deficient mice and analysed the CNS myelin. Surprisingly, the compact myelin was formed, however, the myelin from MOBP-deficient mice exposed to hexachlorophene, a known dysmyelinating agent, showed widening of the major dense lines. These results suggest that MOBP is not essential for myelin formation, but reinforces the apposition of the cytoplasmic faces of the myelin sheath. A striking phenotype of MOBP-deficient mice was the presence of the straight 'condensed' radial component. This component has been described as a tight junction-like complex running radially and zig-zag through the CNS myelin sheath between inner and outer mesaxons. These results suggest that MOBP is essential for normal arrangement of the radial component.

Protein and lipid composition of radial component-enriched CNS myelin

The radial component is a junctional complex that is believed to stabilize the apposition of myelin membranes in the internode of CNS myelin. Based on our previous finding that the radial component of compact myelin retains its structure in tissue treated with the detergent Triton X-100, we have attempted to isolate the junctional complex from spinal cord myelin treated with this detergent. Using 0.5% Triton X-100, our procedures yielded a fraction of isolated myelin that was enriched in well-preserved radial component. This fraction that contained morphologically well-defined radial component was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting, and TLC, and was found to be significantly and consistently enriched in the 21.5-kDa and 17-kDa isoforms of myelin basic protein, and in cerebrosides, hydroxy sulfatide, and sphingomyelin. In addition, the myelin-associated enzyme 2',3'-cyclic nucleotide 3'-phosphodiesterase, tubulin, and actin tended to be resistant to Triton extraction. The fraction of isolated myelin that contained radial component was deficient in proteolipid protein and DM-20, the 18.5- and 14-kDa isoforms of myelin basic proteins, and in the major phospholipids, phosphatidylethanolamine, phosphatidylcholine, and phosphatidylserine. Our data indicate that the radial component can be isolated and that certain myelin and cytoskeletal proteins and lipids are closely associated with it.

Radial component of CNS myelin: junctional subunit structure and supramolecular assembly

The radial component is a structural specialization within CNS myelin that is believed to stabilize the apposition of membranes in the internode. Previous observations on thin sections and freeze-fracture replicas show that this junctional complex consists of linear, particulate strands that run parallel to the nerve fibre axis and radially through the myelin sheath, but details on its molecular organization are lacking. The objective of our current study was to gain further insight into its arrangement and composition by examining its fine-structure and incidence in: myelin with known deficits in protein composition (e.g., shiverer, transgenic shiverer, myelin deficient and jimpy mutant mice); isolated CNS myelin, which has been shown by X-ray diffraction to be more stable than intact CNS myelin; and human white matter, in which this junctional complex has not yet been described. Our results confirm the localization and general appearance of the radial component as previously reported. In addition, we found that: (1) the radial component occurs abundantly in human CNS myelin where it has a complex subunit structure; (2) the constituent junctional unit of this structure is organized as a pair of globular domains (each approximately 40 A diameter) at the extracellular apposition which is linked by approximately 15 A diameter filaments extending through the bilayer to approximately 25 A globular domains in the adjacent cytoplasmic apposition; (3) the radial component is present with apparently normal structure in the sparse, compact myelin of murine mutants containing either different amounts of MBP or no PLP which indicates that neither of these proteins is necessary for junctional integrity; (4) the radial component is present in purified CNS myelin membranes which may account for the stability of these membranes; and (5) the radial component is structurally resistant to Triton, which suggests a method for its further biochemical characterization. Finally, from an analysis of images from tilted transverse and longitudinal sections, we have reconstructed a model of its three-dimensional, supramolecular organization.

Role of the blood-nerve barrier in experimental nerve edema

Nerve edema is a common response to the nerve injury seen in many peripheral neuropathies and is an important component of Wallerian degeneration. However, independent pathologic effects of nerve edema that aggravate or induce nerve injury extend the role of edema beyond that of an epiphenomenon of injury. New insights into the mechanism and impact of nerve edema come largely from animal models. In the following review, we discuss the cause and consequences of nerve edema with particular reference to endoneurial fluid pressure and its relevance to the nerve microenvironment. Experimental models of nerve edema include conditions with increased vascular permeability such as lead poisoning, experimental allergic neuritis, and murine globoid leukodystrophy. Increased perineurial permeability induced by local anesthetics and neurolytic drugs can also induce nerve edema sufficient to increase endoneurial fluid pressure. Both perineurial and vascular permeability are increased after damage induced by crush, freeze, or laser injury. One of the most important forms of nerve edema is induced by external compression; the significance of this change is that edema has local compressive effects that persist after the external pressure has been relaxed. Nerve edema and increased endoneurial fluid pressure also occur in conditions in which vascular permeability appears to be unchanged such as experimental diabetic neuropathy and in hexachlorophene intoxication. In both of these conditions, reduced nerve blood flow has been demonstrated in rats and is viewed as a consequence of increased endoneurial fluid pressure. Whatever its mechanism, endoneurial edema has important structural and functional consequences for nerve fibers. A clear understanding of the underlying pathology of the nerve microenvironment may provide useful insights into treatment of clinical neuropathies.

Topology of proteolipid protein in the myelin membrane of central nervous system. A study using antipeptide antibodies

Peptides according to amino-acid sequences of the N- and C-terminus of lipophilin (proteolipid protein, PLP) (Gly1-Phe15 = 1; Thr261-Phe276 = 6) and of the other four hydrophilic domains (Glu37-Leu60 = 2; Arg97-Leu112 = 3; Gly119-Gly127 = 3A; Trp144-Tyr156 = 3B; Lys191-Ala203 = 4; Asn222-Phe232 = 5) have been synthesized by the solid-phase Fmoc method, linked covalently to keyhole limpet hemocyanin (KLH) and used as antigens. Monospecific antibodies against these antigens were isolated by affinity chromatography. Each antibody recognized its epitope in isolated partially delipidated PLP with the ELISA technique, western blot, thin sections of paraffin embedded rat brains and in the plasma membrane of appropriately fixed/permeabilized rat oligodendrocytes in culture. After fixation with formaldehyde antipeptide 3A antibody stained intact non-permeabilized cells. Therefore the epitope 3A must be located on the extracellular surface of the membrane. This is in full support of our previous biochemical results on the orientation of lipophilin in the myelin membrane.

Differential expression of galactocerebroside, myelin basic protein, and 2',3'-cyclic nucleotide 3'-phosphohydrolase during development of oligodendrocytes in vitro

This paper describes the differential expression and localization of myelin components within membrane sheets produced by oligodendrocytes in vitro. In double-labeling experiments using antibodies to the myelin antigens 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNP) and galactocerebroside (GC), the two antigens were coexpressed in at least 95% of oligodendrocytes at all ages examined. A small population of relatively undifferentiated cells expressed one antigen before the other. Within the membrane sheets produced by the cultured cells, CNP and GC are distributed differently. CNP is highly concentrated in cell bodies, in a network of processes extending from the cell body into the sheets, and around the perimeter of the sheets. CNP staining cannot be detected in some areas within the body of the sheet. When present, it is of low intensity. Under our labeling conditions, GC staining is found throughout the membrane sheets, except in the network of veins which are CNP+. GC and myelin basic protein (MBP) staining are seen in similar membrane domains even though GC is a surface component while MBP resides on the cytoplasmic face. Both the timing and localization of CNP immunostaining show that CNP is as early a marker for oligodendrocytes as GC, and support the idea that CNP may play a structural role in the myelin membrane. Double-labeling studies with GC and CNP antibodies also show that the true shape of a cell and the extent of its development are not always revealed by a single antigen. The differential distribution of antigens within membrane sheets illustrates that they contain areas of structural specialization that may reflect the situation in intact myelin.

Membrane interactions are altered in myelin isolated from central and peripheral nervous system tissues

Isolated myelin has been used for determinations of membrane surface charge density and topographical mapping of components in the membrane. To determine how similar such myelin is to myelin of intact tissue, we have used x-ray diffraction to compare their intermembrane interactions. The interactions were monitored by measuring the myelin period in samples treated with distilled water, buffered saline at pH 4-9 and ionic strength 0.06-0.18, and saline containing HgCl2 or triethyl tin sulfate. Myelin was isolated from whole brains and sciatic nerves of mice by conventional methods involving sucrose gradient centrifugation and osmotic shock. Consistent with previous findings, electron microscopy showed that the multilamellar morphology, staining, and repeat periods of isolated myelin were essentially like those of intact myelin; however, the membrane stacks were less extensive than those in whole tissue. X-ray diffraction revealed that isolated CNS myelin was like intact myelin in showing reversible compaction in acidic media and in distilled water. However, unlike the myelin in whole tissue, isolated CNS myelin did not swell in hypotonic or alkaline media, or in the presence of HgCl2-saline or triethyl tin. The altered membrane interactions could result from an increase in adhesiveness of the apposed membrane surfaces. Reorganization of proteolipid protein and/or a reduction of surface charge could account for the change in surface properties of isolated CNS myelin. Isolated PNS myelin, like the membranes in whole tissue, showed both compaction and swelling; however, the membrane pairs were disordered in the swollen structure. This irregular membrane swelling could result from charge variation in the extracellular surfaces.

Triton X-100 extractions of central nervous system myelin indicate a possible role for the minor myelin proteins in the stability in lamellae

Isolated CNS myelin membranes were extracted with Triton X-100 under conditions previously established for the isolation of cytoskeletal proteins. Treated myelin retained much of its characteristic lamellar structure despite the removal of most of the major myelin basic protein (18.5 kDa) and the proteolipid protein, which together normally constitute 60% of the total myelin protein. The SDS-PAGE profile of this extract residue demonstrated an enrichment in proteins of Mr 30 to 60 kilodaltons (the Wolfgram group). The major myelin proteins were identified by antibodies on Western immunoblots, as were the 2'3'-cyclic nucleotide 3'-phosphodiesterase (CNP), actin, tubulin, myelin-associated glycoprotein (MGP) and the 21.5 kDA MBP. The overall behavior of CNP, the 21.5 kDa MBP, MGP and tubulin towards Triton extraction is reminiscent of the behavior of other membrane-skeletal complexes, supporting the idea that these and other minor myelin proteins might be part of heteromolecular complexes with interactions spanning several lamellae of the myelin sheath.

A new myelin-deficient mutant hamster: biochemical and morphological studies

Biochemical and morphological studies were done on a new trembling mutant hamster CBB. The yield of myelin from the mutant was 30 and 40% of the control at 46 and 140 days of age, respectively, but myelin composition and 2',3'-cyclic nucleotide-3'-phosphohydrolase (CNPase) activity were normal. Morphologically, about 18% of the axons were myelinated in the mutant optic nerve at 46 days of age, in which the myelinated fibers were those with larger diameters (more than 0.6 micron), while the control had a peak at 0.4 micron in diameter. The ultrastructure and thickness of compact myelin lamellae in the mutant were normal. Myelination and the structure of peripheral nerve myelin appeared normal. The results indicate that the essential defect is the delay and arrest of myelination in the CNS, which is probably caused by either a decreased rate of synthesis of myelin components in oligodendrocytes or a defect in the oligodendrocyte-axon recognition in smaller axons.

Localizations of ruthenium red positive material in rabbit peripheral nerves

The penetration and distribution of ruthenium red in the axon-myelin-Schwann cell complex of developing rabbit peripheral nerve fibers are investigated. Ruthenium red positive material is established in the axoplasm, axolemma, periaxonal space, major dense lines and intraperiod lines of the compact myelin, mesaxons, split peripheral myelin lamellae, Schmidt-Lanterman and longitudinal incisures, paranodal loops and axo-glial contacts, Schwann cell cytoplasm and basal lamina, nodal extracellular matrix, desmosome-like structures, endoneural collagen. Some features of the distribution of the contrast material in the developing myelin sheath are described. Regional differences of the axolemma and of the Schwann cell cytoplasm and plasmalemma are established. The prevalence of glycoproteins or glycolipids in the ruthenium red stained material in its different localizations is discussed on the basis of trypsin and hyaluronidase digestion performed.

Electron microscopic demonstration of polysaccharides in central and peripheral myelin by thiosemicarbazide-protein-silver staining

Thin sections of glutaraldehyde-fixed central and peripheral nerve myelin were stained with thiosemicarbazide and protein-silver after oxidation with periodic acid on thin sections. In compact CNS myelin, staining was observed exclusively on intraperiod lines. In peripheral myelin, both intraperiod and major dense lines were stained. In addition, dense staining was observed on plasma membranes of oligodendrocytes and Schwann cells, especially periaxonally on tongue processes and in Schmidt-Lanterman incisures. The observed staining was most prominent on glycogen granules in unfixed and freeze-substituted tissues. Therefore, the results strongly suggest that polysaccharides of glycoproteins and glycolipids are visualized in both CNS and PNS compact myelin as well as on surface membranes of oligodendrocytes and Schwann cells.

Ultracytochemical localization of ouabain-sensitive K+-dependent, p-nitrophenyl phosphatase in myelin

Ouabain-sensitive, K+-dependent p-nitrophenyl phosphatase (K-NPPase) activity was demonstrated ultracytochemically in the myelin of nerve fibers in peripheral and central white matter. Enzyme activity was more prominent in paranodal than compact myelin, and it was absent from nodal and interparanodal axolemma. Since K-NPPase is part of the Na-KATPase complex, we consider myelin as an important site of the sodium pump and believe that myelin participates in cationic regulation of the nervous tissue.

Nodes of Ranvier and Schmidt-Lanterman incisures: an in vivo lanthanum tracer study

The permeability of the tight junctional system of myelin, at the juxtanodal myelin terminal loops and Schmidt-Lanterman incisures, was investigated using the ionic tracer lanthanum (a) in vivo followed by fixation, (b) concurrently with fixation, (c) following fixation. Employing the same methods the juxtanodal membrane complex formed between myelin loops and axolemma was also tested. The results of this study demonstrate that the periaxonal space (between axon and Schwann cell) is apparently accessible to lanthanum via the myelin loop-axolemmal junction, irrespective of the mode of exposure of myelinated fibres to the tracer. Similarly, the tight junctions between adjacent myelin terminal loops apparently do not prevent lanthanum penetration either in living or in fixed nerves. By contrast the tracer obtained access to the extracellular space within incisures only in vivo. The results are interpreted in terms of the permeability of nodes and incisures in vivo to physiologically important ions and related to current concepts of the electrophysiology of the myelinated nerve fibre.

New X-ray spacings from central myelinated tissue

New X-ray reflections have been detected from myelinated tissue of the mammalian C.N.S. Diffraction patterns from unfixed optic nerves of mouse, rat, guinea-pig and rabbit, and unfixed corpus callosum of calf were recorded during X-ray exposures of 1-6 days. The equatorial pattern was typical of lamellar myelin of the C.N.S.; however, the meridional pattern showed new features: a strong, sharp intensity maximum at 30.4 +/- 0.4 A (N = 11) spacing, and a weak, diffuse ring centered at 11.0 +/- 0.5 A (N = 5) spacing. The 30.4 A reflection was neither strictly arced like the equatorial reflections from lamellar myelin nor fully horizontal. Since the 30.4 A meridional reflection was not observed in patterns from myelinated nerve of the P.N.S., we suggest that this diffraction comes from the radial component, or interlamellar tight junctions, which is unique to mammalian C.N.S. myelinated tissue. The diffuse ring at 11.0 A probably comes from myelin protein.

Radial component of central myelin in shiverer mouse

'Radial component' of the central myelin was investigated in a neurological mutant mouse, shiverer, which is characterized by the lack of myelin basic protein and paucity of the major dense line in the CNS myelin. As has been noted previously in the normal as well as other neurological mutant mice, radial component consisted of rows of interlamellar tight junctions and was accompanied with electron lucent linear structures (ELLS) over the major dense lines. In the areas where major dense line had formed in shiverer CNS myelin, numerous ELLS run across the major dense lines and were not always associated with a fusion of double intraperiod lines. The possible role of ELLS in myelin formation is briefly discussed.

Myelinating glia of earthworm giant axons: thermally induced intramembranous changes

The median and lateral giant axons in the ventral nerve cord of the earthworm Lumbricus terrestris are ensheathed by extensive spiral glial cell wrappings which resemble vertebrate myelin. The other, smaller, axons are encompassed by attenuated glial processes, as is typical of invertebrates. The fine structural details of the glial cells have been studied in thin sections and in replicas produced by freeze-fracturing where the intramembranous particle (IMP) populations within the lipid bilayer are visible. These consist of both low-profile IMPs as well as prominent ones 6-8 nm in diameter, scattered at random over the lipid interface in the myelinating glia. The larger IMPs on both P and E faces number about 80/mum2 at 16 degrees C in contrast to the IMP density of 400/mum2 in the other glial membranes. After acclimation to 5, 16 and 26 degrees C, the loose myelin glial membranes show variations in the density of their larger IMP population; in animals acclimated over 3 or more weeks to 5 degrees C, the number of these IMPs is significantly (P less than 0.001) less per unit area than in animals acclimated to 16 or 26 degrees C. The size of the particles at 5 degrees C is significantly (P less than 0.001) smaller than those at 16 or 26 degrees C. When animals are subjected to a sudden differential in ambient temperature, from 26 or 16 to 5 degrees C, or from 5 to 26 degrees C, and their giant axons with encompassing glia are fixed and frozen 30 min after this temperature change, the IMP population of the glial membranes remaining does not appear to alter. The differences in the IMP population of the myelinating glial membranes at different temperatures may reflect the extent to which they insulate and/or influence the velocity of impulse propagation.

Formation of misplaced and reflexive tight junction strands in prostate epithelial cells

Tight junction strands occur at three atypical locations in slices of rat ventral prostate exposed to conditions promoting rapid tight junction assembly: (1) in the basal plasma membranes of the columnar epithelial cells, over 40 microns from the native apical tight junction band (misplaced tight junctions); (2) in the plasma membranes of basal epithelial cells, which never have tight junctions in the native state; and (3) between processes of the same cell (reflexive or autocellular tight junctions) at the basal or lateral portions of the columnar epithelial cell. These findings suggest that tight junction formation is not limited to specific parts of the plasma membrane, even in highly polarized cells such as those in prostate epithelium. Taken together with other new evidence, they also suggest that tight junctions may be very labile.

Tight junction contact events and temporary gap junctions in the sciatic nerve fibres of the chicken during Wallerian degeneration and subsequent regeneration

Tight and gap junctions are described on the basis of freeze-fractures in normal chicken sciatic nerves as well as during Wallerian degeneration and subsequent regeneration. 1. Small calibre nerve fibres display a fairly continuous tight junction contact zone in the membranes of the mesaxons, paranodal loops and Schmidt-Lanterman incisures. Large fibres with more than 40 lamellae have only focal tight junction contacts in the mesaxonal membranes. 2. With the onset of Wallerian degeneration (days 2-4 post-crush, distal stump) myelinic tight junctions become arranged as maculae composed of one circular or several polygonally oriented strands that are criss-crossed by other tight junctional strands. These maculae are subsequently found in the membranes of cytoplasmic vacuoles of the Schwann cells, indicating an endocytotic mode of uptake. Tight junctions are not found between the 5th and 6th day after crush. 3. During the proliferation phase of the Schwann cells and the arrangement of these cells into Büngner cell bands (2 to 8 days post-crush) gap junctions appear between the Schwann cells of the bands. These junctions then disappear with the onset of remyelination (8 days post-crush). 4. With the onset of remyelination (from the 8th day onwards) short focal tight junctions appear in the membranes of the outer mesaxons. Shortly thereafter, when the sheaths possess 4 to 8 lamellae, tight junctions also appear in the membranes of the inner mesaxons, the paranodal loops and the cytoplasmic inclusions. The characteristic differences of tight junction elaboration in small versus large nerve fibres are re-established after three months of regeneration. The elaborated tight junctions in small and early remyelinating fibres point to a specific function; in small fibres (versus large fibres) the tight junctions might effect a separation of the intramyelinic extracellular space as a single compartment. The tight junction contacts in early remyelinating fibres support the hypothesis that myelin growth occurs within the myelin spiral and not by a free rotation and elongation of the Schwann cell tongues. It is assumed that the gap junctions between the Schwann cells contribute to the co-ordination of the Schwann cell band formation, which is involved in the guidance of sprouting axons.

Repetitive propagation of action potentials destabilizes the structure of the myelin sheath. A dynamic x-ray diffraction study

Time courses of myelin lattice swelling in toad sciatic nerves preexposed to different treatments were determined by x-ray diffraction using a one-dimensional position-sensitive detector. In the nerves supramaximally stimulated for 1 h at 200 Hz, the subsequent process of myelin swelling occurred 45.0 +/- 7.3 min (n = 24) sooner than in resting controls. Sciatic nerves incubated for 1 h in a Ringer's solution deprived of divalent cations (Ca++ and Mg++) exhibited a kinetics of swelling similar to that shown by the stimulated nerves, that is, 52.5 +/- 14.2 min (n = 6) sooner than controls preincubated for the same time in normal Ringer's solution (with divalent cations). The fact that both pretreatments supramaximal stimulation and removal of divalent cations from the perfusion solution produced a similar effect; namely, a decrease of the myelin lattice stability against swelling in distilled water, suggests that the repetitive propagation of action potentials could modify the ionic composition at either the intraperiod channel or the paranodal axoglial junction complexes.

Cell junctions and intramembrane particles of astrocytes and oligodendrocytes: a freeze-fracture study

The plasma membranes of astrocytes and oligondendrocytes in the white matter of the cat were studied with the freeze-fracturing technique. The intramembrane particle profiles differ in the two type of cell. Orthogonal, small particle assembles and isolated globular particles 5-18 nm in diameter characterize the astrocytic plasmalemma, whereas the plasma membrane of oligodendrocytes shows large, tall globular particles, small globular particles, small ellipsoidal particles and previously undescribed, thin, short, rectilinear strands composed of fused subunits. Using these distinct differential features we can identify partners of glial cell junctions. We confirm the existence of interastrocytic gap junctions. Moreover, we identify numerous heterologous gap junctions between astrocytes and oligodendrocytic cell bodies, processes and the outer turn of myelin sheaths. Interoligodendrocytic gap junctions are not observed. Adjacent oligodendrocytes, however, form tight junctions consisting of linear P face strands and rows of particles; tight junctions are a reliable marker for oligodendroglial membranes. Connexons of interastrocytic gap junctions are packed in a crystalline array, while astrocyte-oligodendrocyte junctional connexons are closely packed but not crystalline. This study indicates that gap junctions between glial cells are pleomorphic and non-randomly distributed. The junctions between astrocytes and those between astrocytes and oligodendrocytes may had different roles in interglial and neuron-glia cooperation.

Triethyl tin does not induce intramyelinic vacuoles in the cns of the quaking mouse

Triethyl tin (TET), when injected intraperitoneally, failed to produce the typical intramyelinic edema in the spinal cord of quaking mice with two different genetic backgrounds (B6C3H-qk and BTBRTF/Nev-qk), while control littermates and normal C57BL/6J mice were susceptible, as expected. The only prominent change in the quaking mice was the presence of spherical vacuoles containing floccular electron-dense materials, some of which were clearly within the oligodendroglial perikarya and the inner and outer tongues. They are likely to represent degenerative responses. Consistent with the lack of edema, no increase in the water content was found in the quaking spinal cord following TET injection. Although the presence of numerous interlamellar tight junctions in quaking CNS myelin may mechanically restrict formation of the intralamellar vacuoles, the unique changes in the oligodendroglia and the lack of edema fluid accumulation suggest more fundamental metabolic abnormality that renders the quaking CNS resistant to the triethyl tin-induced edema.

The periaxonal space in an experimental model of neuropathy: the mutant Syrian hamster with hindleg paralysis

The periaxonal space of peripheral myelinated axons was studied in the mutant Syrian hamster with hindleg paralysis, an experimental model of neuropathy. Despite pronounced alterations of the axon and the surrounding sheath, sometimes leading to demyelination, the periaxonal space showed remarkable resistance to change in most instances. When the space was widened as the result of the infiltration of extracellular fluid, the axon was found at the periphery of the enlarged inner perimeter of the sheath. Even under these extreme conditions the axon maintained close to normal distance from the inner collar of cytoplasm. The significance of these findings with regard to both the normal anatomical relationship within the sheath and to the mechanisms of demyelination are discussed.

Radial component of central myelin in normal and quaking mice

Radial component of myelin sheaths was investigated in C57BL and quaking mice. In immature myelinated fibres of C57BL mice, more than one group of radial component were observed in the several regions of myelin sheaths while in mature fibres, one group of radial component was localized between the internal mesaxon and outer tongue process which were situated within 90 degrees of each other. In thinly myelinated fibres of adult quaking mice, numerous groups of radial component were found at random distance and directions but they were always closely related to the cytoplasmic islands of oligodendroglia. Even in quaking mice, small well myelinated fibres showed normal mature pattern of radial component. Possible functional significance of radial component was briefly discussed.

Interlamellar tight junctions of central myelin. I. Developmental mechanisms during myelogenesis

The process of myelination in the central nervous system (CNS) of the rat (optic nerve) was studied with the freeze-fracturing technique and ultrathin sectioning to obtain information on the developmental mechanisms of interlamellar tight junctions. Using a tilting cartridge for analysis of thin sections, it could be demonstrated that during the initial phase of wrapping a tight junction formation develops between the joining tips of the oligodendrocytic process. In tannic acid-stained samples these junctions appear as typical quintuple-layered membrane fusions, while in potassium permanganate-stained material membrane thickenings between the apposing glial tips are prevalent. The latter configuration represents the characteristic feature of the so-called radial component of central myelin. Using the freeze-fracturing technique, a biphasic mode of the myelinic tight junction assembly was detected. It is suggested that tight junctions represent a prerequisite of the myelination process.

Interlamellar tight junctions of central myelin. II. A freeze fracture and cytochemical study on their arrangement and composition

The interlamellar tight junctions (ITJ) of central myelin (white matter from the parietal lobe and the medulla oblongata of the rat) were analyzed electron microscopically, making use of a wide range of different preparatory techniques. Freeze-fracture observations indicate that the ITJ are composed of rows of particulate subunits in glutaraldehyde-fixed or formaldehyde-fixed material, and in the unfixed state. The particulate subunits of the ITJ are preferentially associated with the protoplasmic (P) face in the aldehyde-fixed state, and no shift in the binding characteristics of the particles was observed after omission of aldehyde fixation. Tracer studies in conjunction with the dissociated appearance of the junctional globules suggest that the ITJ represent a leaky type of zonula occludens. It is assumed that the ITJ particles represent an "integral-type protein" that preferentially serves as a mechanical device maintaining the structural integrity of the central myelin sheath. By means of cytochemical experiments, the proteinaceous character of the ITJ subunits is established. An attempt is made, based on results from lipid extraction and protein digestion, to define certain cytochemical parameters of the ITJ proteins and to compare them with the current collection of chemically identified proteins of central myelin.

Comparative analysis of junctions in the myelin sheath of central and peripheral axons of fish, amphibians and mammals: a freeze-fracture study using complementary replicas

Tight junction-like structures are found in freeze-fractured myelin of the peripheral and central nervous system of the electric eel and trout, but not in the electric ray, Torpedo californicus. Myelin junctions are more difficult to find in the peripheral myelin of Xenopus frogs and of mice and rats, except in the myelinating fibres of young animals. Junctions are most frequently seen at the outer mesaxons, but are also observed at the inner mesaxons, paranodal loops, incisures of Schmidt-Lanterman and in compact myelin. The junctional strands vary considerably in appearance; instead of displaying the extensive strands and grooves of typical tight junctions, they are usually particulate with single or fused particles, short strands, and corresponding pits and grooves. After fixation, elements of the junctions partition between P- and E-faces with the majority of particles remaining with the P-face. In unfixed fish myelin, strands often remain with the E-face but fixation does not greatly alter the appearance of rat myelin. Complementary replicas show that junctions are often discontinuous. The significance of the distribution and morphology of junctions among the different specimens examined is discussed with regard to the possible functions and maintenance of myelin junctions.

E-PTA stains oligodendroglial surface membranes and microtubules in optic nerves during myelination

Aldehyde fixed Xenopus tadpole and frog optic nerves were stained en bloc with ethanolic phosphotungstic acid (E-PTA). During rapid myelination, intense staining was observed on cytoplasmic faces of paranodal terminal loops and loosely wrapped oligodendroglial membranes found along inner and outer surfaces of compact myelin sheaths. Oligodendroglial microtubules also were heavily stained. Where stained cytoplasmic faces fused to form a lamella of compact myelin, the intense staining was reduced to a thinner, fainter line. In optic nerves of adult frogs, the staining was less dense but the pattern was similar. The staining distribution and available histochemical evidence indicate that E-PTA stains positively charged proteins non specifically. Since myelin basic protein is found in oligodendroglia during myelination, we suggest that it is being stained by E-PTA while being transported along microtubules to sites where it is inserted into developing myelin lamellae.

Occluding-like junctions at mesaxons of central myelin in Anolis carolinensis are not 'tight'. A freeze-fracture-protein tracer analysis

The junctional complexes of the myelin sheath of central nervous system axons in the American chameleon, Anolis carolinensis, exhibit an intramembrane ridge and groove construction in freeze-fracture replicas that has usually been interpreted in other organisms as evidence for an occluding or tight intercellular junction. Close examination of PF fracture face ridges, however, shows them to be made up of discontinuous rows of particles of variable length separated by frequent gaps of non-uniform width. Introduction of horseradish peroxidase into the intercellular milieu of the lizard central nervous system is followed by appearance of this protein in interlamellar spaces of the myelin sheath and in the intercellular spaces containing focal membrane fusions that correspond precisely in position and center-to-center spacing to the ridges and grooves in platinum replicas of the same tissue. Since the junctional ridges on PF fracture faces in these mesaxonal junctional complexes are conspicuously discontinuous and since the areas within the myelin sheath where these junctional complexes are located inner and outer mesaxons) are readily permeated by exogenous protein tracer, it is concluded that the junctional complexes of central myelin mesaxons, heretofore incorrectly interpreted as functionally tight, are actually very leaky and probably contribute only to the structural stability of the myelin sheath architecture.