The mechanosensitive ion channel TRAAK is localized to the mammalian node of Ranvier.

TRAAK is a membrane tension-activated K+ channel that has been associated through behavioral studies to mechanical nociception. We used specific monoclonal antibodies in mice to show that TRAAK is localized exclusively to nodes of Ranvier, the action potential propagating elements of myelinated nerve fibers. Approximately 80 percent of myelinated nerve fibers throughout the central and peripheral nervous system contain TRAAK in what is likely an all-nodes or no-nodes per axon fashion. TRAAK is not observed at the axon initial segment where action potentials are first generated. We used polyclonal antibodies, the TRAAK inhibitor RU2 and node clamp amplifiers to demonstrate the presence and functional properties of TRAAK in rat nerve fibers. TRAAK contributes to the 'leak' K+ current in mammalian nerve fiber conduction by hyperpolarizing the resting membrane potential, thereby increasing Na+ channel availability for action potential propagation. We speculate on why nodes of Ranvier contain a mechanosensitive K+ channel.

Activity-dependent regulation of mitochondrial motility by calcium and Na/K-ATPase at nodes of Ranvier of myelinated nerves.

The node of Ranvier is a tiny segment of a myelinated fiber with various types of specializations adapted for generation of high-speed nerve impulses. It is ionically specialized with respect to ion channel segregation and ionic fluxes, and metabolically specialized in ionic pump expression and mitochondrial density augmentation. This report examines the interplay of three important parameters (calcium fluxes, Na pumps, mitochondrial motility) at nodes of Ranvier in frog during normal nerve activity. First, we used calcium dyes to resolve a highly localized elevation in axonal calcium at a node of Ranvier during action potentials, and showed that this calcium elevation retards mitochondrial motility during nerve impulses. Second, we found, surprisingly, that physiologic activation of the Na pumps retards mitochondrial motility. Blocking Na pumps alone greatly prevents action potentials from retarding mitochondrial motility, which reveals that mitochondrial motility is coupled to Na/K-ATPase. In conclusion, we suggest that during normal nerve activity, Ca elevation and activation of Na/K-ATPase act, possibly in a synergistic manner, to recruit mitochondria to a node of Ranvier to match metabolic needs.

Na+ channels get anchored...with a little help.

Neurons have high densities of voltage-gated Na(+) channels that are restricted to axon initial segments and nodes of Ranvier, where they are responsible for initiating and propagating action potentials. New findings (Bréchet, A., M.-P. Fache, A. Brachet, G. Ferracci, A. Baude, M. Irondelle, S. Pereira, C. Leterrier, and B. Dargent. 2008. J. Cell Biol. 183:1101-1114) reveal that phosphorylation of several key serine residues by the protein kinase CK2 regulates Na(+) channel interactions with ankyrin G. The presence of CK2 at the axon initial segment and nodes of Ranvier provides a mechanism to regulate the specific accumulation and retention of Na(+) channels within these important domains.

Protein kinase CK2 contributes to the organization of sodium channels in axonal membranes by regulating their interactions with ankyrin G.

In neurons, generation and propagation of action potentials requires the precise accumulation of sodium channels at the axonal initial segment (AIS) and in the nodes of Ranvier through ankyrin G scaffolding. We found that the ankyrin-binding motif of Na(v)1.2 that determines channel concentration at the AIS depends on a glutamate residue (E1111), but also on several serine residues (S1112, S1124, and S1126). We showed that phosphorylation of these residues by protein kinase CK2 (CK2) regulates Na(v) channel interaction with ankyrins. Furthermore, we observed that CK2 is highly enriched at the AIS and the nodes of Ranvier in vivo. An ion channel chimera containing the Na(v)1.2 ankyrin-binding motif perturbed endogenous sodium channel accumulation at the AIS, whereas phosphorylation-deficient chimeras did not. Finally, inhibition of CK2 activity reduced sodium channel accumulation at the AIS of neurons. In conclusion, CK2 contributes to sodium channel organization by regulating their interaction with ankyrin G.

Accumulation of phosphorylated I kappaB alpha and activated IKK in nodes of Ranvier.

AIMS: Nuclear factor-kappaB (NF-kappaB) is an ubiquitously expressed transcription factor that modulates inducible gene transcription crucial for the regulation of immunity, inflammatory processes, and cell survival. In the mammalian nervous system, constitutive NF-kappaB activation is considered to promote neuronal cell survival by preventing apoptosis. Increasing evidence suggests a critical role for NF-kappaB activation in acute and chronic neurodegenerative diseases. Recently, a striking enrichment of phosphorylated I kappaB alpha (pI kappaB alpha) and activated I KappaB Kinase (IKK), two key components of the NF-kappaB activation pathway, was demonstrated in the axon initial segment (AIS) of neurons. As the AIS shares fundamental features with nodes of Ranvier (NR), we examined whether pI kappaB alpha and activated IKK are also enriched in NR. METHODS: Double-immunofluorescence labelling was performed with vibratome sections of the rodent central and peripheral nervous system. Sections were analysed using confocal laser scanning microscopy and preembedding electron microscopy. RESULTS: Here we report a remarkable accumulation of pI kappaB alpha and activated IKK in NR in the central and peripheral nervous system. Immunolabelling for both proteins extended from NR into the adjacent paranode. pI kappaB alpha predominantly accumulated within the cytoplasm and was associated with fasciculated microtubules. This association was confirmed by electron microscopy. By comparison, activated IKK preferentially clustered beneath the cytoplasmic membrane. CONCLUSION: In conclusion, the coincident accumulation of pI kappaB alpha and activated IKK in AIS and NR suggests that these specific axonal compartments contribute to neuronal NF-kappaB activation.

Postnatal development of alkaline phosphatase activity correlates with the maturation of neurotransmission in the cerebral cortex.

We have shown previously that the tissue nonspecific alkaline phosphatase (TNAP) is selectively expressed in the synaptic cleft of sensory cortical areas in adult mammals and, by using sensory deprivation, that TNAP activity depends on thalamocortical activity. We further analyzed this structural functional relationship by comparing the developmental pattern of TNAP activity to the maturation of the thalamocortical afferents in the primate brain (Callithrix jacchus). Cortical expression of alkaline phosphatase (AP) activity reflects the sequential maturation of the modality-specific sensory areas. Within the visual cortex, the regional and laminar distribution of AP correlates with the differential maturation of the magno- and parvocellular streams. AP activity, which is transiently expressed in the white matter, exhibits a complementary distributional pattern with myelin staining. Ultrastructural analysis revealed that AP activity is localized exclusively to the myelin-free axonal segments, including the node of Ranvier. It was also found that AP activity is gradually expressed in parallel with the maturation of synaptic contacts in the neuropile. These data suggest the involvement of AP, in addition to neurotransmitter synthesis previously suggested in the adult, in synaptic stabilization and in myelin pattern formation and put forward a role of AP in cortical plasticity and brain disorders.

CNP is required for maintenance of axon-glia interactions at nodes of Ranvier in the CNS.

Axoglial interactions underlie the clustering of ion channels and of cell adhesion molecules, regulate gene expression, and control cell survival. We report that Cnp1-null mice, lacking expression of the myelin protein cyclic nucleotide phosphodiesterase (CNP), have disrupted axoglial interactions in the central nervous system (CNS). Nodal sodium channels (Nav) and paranodal adhesion proteins (Caspr) are initially clustered normally, but become progressively disorganized with age. These changes are characterized by mislocalized Caspr immunostaining, combined with a decrease of clustered Na+ channels, and occur before axonal degeneration and microglial invasion, both prominent in older Cnp1-null mice. We suggest that CNP is a glial protein required for maintaining the integrity of paranodes and that disrupted axoglial signaling at this site underlies progressive axonal degeneration, observed later in the CNS of Cnp1-null mice.

Localization of Na,K-ATPase alpha/beta isoforms in rat sciatic nerves: effect of diabetes and fish oil treatment.

The localization of the Na,K-ATPase isoenzymes in sciatic nerve remains controversial, as well as diabetes-induced changes in Na,K-ATPase isoforms. Some of these changes could be prevented by fish oil therapy. The aim of this study was to determine by confocal microscopy the distribution of Na,K-ATPase isoforms (alpha1, alpha2, alpha3, beta1, and beta2) in the sciatic nerve, the changes induced by diabetes, and the preventive effect of fish oil in diabetic neuropathy. This study was performed in three groups of rats. In the first two groups, diabetes was induced by streptozotocin and rats were supplemented daily with fish oil or olive oil at a dosage of 0.5 g/kg of body weight. The third one was a control group that was supplemented with olive oil. Five antibodies against specific epitopes of Na,K-ATPase isoenzymes were applied to stained dissociated nerve fibers with fluorescent secondary antibodies. The five isoenzymes were documented in nonspecific regions, Schwann cells (myelin), and the node of Ranvier. The localization of the alpha1, alpha2, and beta1 isoenzymes was not affected by diabetes. In contrast, diabetes induced a decrease of the alpha2 subunit (p < 0.05) and an up-regulation of the beta2 subunit (p < 0.05). These modifications were noted in both regions for alpha2 and were localized at the myelin domain only for the beta2. Fish oil supplementation prevented the diabetes-induced changes in the alpha2 subunit with an additional up-regulation. The beta2 subunit was not modified. A phenotypic change similar to nerve injury was induced by diabetes. Fish oil supplementation partially prevented some of these changes.

Impaired Ranvier node sodium-potassium adenosine triphosphatase may induce facial palsy.

To clarify the part of the neuron essential for myelinated nerve conduction, the cytochemical localization of potassium ion (K+)-dependent p-nitrophenylphosphatase (K-NPPase) activity was investigated in the normal and reserpine-treated facial nerve of guinea pigs. In the normal animals, K-NPPase activity was localized to the internodal axolemma and Schmidt-Lanterman incisures. In the Ranvier nodes, enzyme activity was observed along the paranodal and nodal axolemma. In reserpinized nerves, K-NPPase activity was absent along the internodal axolemma and Schmidt-Lanterman incisures. In the Ranvier nodes, however, enzyme activity was detectable only in the nodal axolemma. The reserpinized animals demonstrated no evidence of facial palsy. Because K-NPPase is essential for nerve conduction, these results indicate that the location of enzyme activity in reserpinized animals, namely the nodal axolemma, may be of prime importance in saltatory nerve conduction.

Fine localization of low and high calcium dependent ATPase activities in the rat sciatic nerve.

We tried to demonstrate the electron microscopic histochemical localization of membrane Ca(2+)-ATPase activity in glutaraldehyde-fixed rat sciatic nerves. Although conventional glutaraldehyde fixatives containing impurities interfered with the reactivity of Ca(2+)-ATPase, this activity was successfully preserved in the tissues fixed with pure glutaraldehyde as well as in those fixed with paraformaldehyde. In unmyelinated nerve fibers, an ATPase activity depending on 10 mM CaCl2 was detected on the whole external surface of Schwann cell plasma membranes. In myelinated fibers, this activity was localized on the surface of Schwann cell outer loops at the paranodal region of Ranvier nodes and on the axonal membrane at the nodal region. Another activity depending on 0.1 mM CaCl2 was demonstrated on the axolemma of unmyelinated fibers. These results indicated that there may be two types of Ca(2+)-ATPase activities showing high and low affinity to calcium ions localized in peripheral nerve systems in a different manner between myelinated and unmyelinated fibers.

Ca++-ATPase in the central nervous system: an EM cytochemical study.

Ca++-ATPase plays an important role in regulation of the intracellular Ca++ concentration. Biochemical studies of brain have demonstrated that Ca++-ATPase co-purifies with synaptosomes, with synaptic plasma membrane and synaptic vesicle fractions. To better understand the role of this enzyme in normal brain function, we used an electron microscopic (EM) cytochemical method to determine the localization of Ca++-ATPase in rat brain. Reaction product occurred along cytoplasmic membranes. Specific areas of increased reaction product were seen at many but not all post-synaptic densities. Intracellular Ca++-ATPase reaction product was associated with all synaptic vesicles examined and with the Golgi and smooth endoplasmic reticulum (SER). Unlike the situation in peripheral nerve, Ca++-ATPase at the node of Ranvier in the CNS localized preferentially to the nodal axolemma. The localization of Ca++-ATPase at synaptic vesicles agrees with the biochemical evidence for its localization and with the cytochemical evidence for Ca++-ATPase sequestration in those vesicles. The restricted localization at postsynaptic densities suggests that it may be involved in extrusion of Ca++ at synapses where neurotransmitter release causes Ca++ influx.

Acid phosphatase activity at nodes of Ranvier in alpha-motor and dorsal root ganglion neurons of the cat.

Acid phosphatase (AcPase) activity in feline alpha-motor and dorsal root ganglion (DRG) neurons was analysed histochemically by light and electron microscopy. The occurrence and distribution of the AcPase activity expressed within the axon differed depending on neuron type and distance from the cell body. Both in alpha-motor and DRG neurons, AcPase-positive bodies of various morphological categories were observed mainly at nodes of Ranvier, where they were more frequent distal than proximal to the nodal midlevel. In the peripherally located processes of both neuron types, most of the larger AcPase-positive bodies were associated with the paranodal axon-Schwann cell network. In the centrally located processes the AcPase-positive bodies were situated in the constricted axon segment and the adjacent paranodal axoplasm. Both in motor and DRG axons, AcPase-positive bodies were more frequent at the spinal root level than at a level central to the PNS-CNS borderline. The observations indicate that lysosomes (i.e. AcPase-positive bodies) constitute part of the intra-axonal system of organelles in normal, large, myelinated alpha-motor and DRG axons of the cat. Lysosome-mediated degradation of retrogradely transported endogenous and exogenous materials may be extensive in normal peripherally directed neuronal processes. The study also suggests a difference between PNS and CNS parts of the same axon with regard to the local turnover of lysosomal organelles.

Peroxidase activity at CNS nodes of Ranvier and in initial axon segments of lumbosacral alpha-motoneurons after intramuscular administration of horseradish peroxidase.

The occurrence of peroxidase activity in central (CNS) and peripheral nervous system (PNS) parts of alpha-motor axons was studied by light and electron microscopy in adult cats after injection of horseradish peroxidase (HRP) into the medial gastrocnemius muscle. The intrafunicular parts of the axons were virtually free of HRP-positive bodies except at a few nodes of Ranvier. Most of these nodes were weakly HRP-positive and contained, irrespective of a survival time between 25 and 48 h, only a few HRP-positive bodies randomly scattered in the nodal axoplasm. In contrast to this and as described elsewhere (J. Neurocytol., 15 [1986] 253-260), the nodal regions of alpha-motor axons at the level of the ventral root showed strong and characteristic accumulations of HRP-activity. The initial axon segments and adjoining axonal parts contained many HRP-positive bodies. We conclude that the CNS and the PNS parts of an alpha-motor axon differ with regard to the way nodal regions interact with retrogradely transported HRP. Possible mechanisms behind this difference are discussed.

The distribution of (Na+ + K+)ATPase is continuous along the axolemma of unensheathed axons from spinal roots of 'dystrophic' mice.

(Na+ + K+)ATPase-like immunoreactivity along the axolemma of sensory and motor neurons and the plasmalemma of Schwann cells from spinal roots of dystrophic mice (129 ReJ Dy/Dy) was determined using polyclonal antibodies specific for guinea pig renal (Na+ + K+)ATPase (GP-17), along with polyclonal (439-2) and monoclonal (9A5) antibodies specific for rat renal (Na+ + K+)ATPase. In normal and dystrophic mice, (Na+ + K+)ATPase-like immunoreactivity was observed along the axolemma at nodes of Ranvier using GP-17 and 439-2, each of which binds to isozymes of (Na+ + K+)ATPase composed of the alpha and alpha + forms of the catalytic subunit. Staining was not seen along the nodal axolemma with 9A5, a preparation that binds to the alpha form of the catalytic subunit. The terminal processes and microvilli of Schwann cells were stained using all three antibody probes. The axolemma of unensheathed axons in dystrophic mice was continuously and uniformly labelled with GP-17 and 439-2, but not 9A5. Concentrations of (Na+ + K+)ATPase-like immunoreactivity along Schwann cell processes were observed most often in areas adjacent to unensheathed axolemma. At heminodes, staining abruptly decreased along Schwann cell processes in areas that were separated from the unensheathed axolemma by other intervening Schwann cell processes. It was concluded from these data that in dystrophic mice (Na+ + K+)ATPase is uniformly distributed along unensheathed portions of axons without evidence of detectable focal concentrations of the enzyme, and that the catalytic subunit of (Na+ + K+)ATPase along unensheathed axons is distinct from the alpha form found in Schwann cells and other organs. In addition, (Na+ + K+)ATPase is concentrated along the plasmalemma of Schwann cells in regions of close apposition to axolemmal areas associated with large ionic fluxes.

Peroxidase activity at nodes of ranvier in lumbosacral ventral spinal roots and in the PNS-CNS transitional region after intramuscular administration of horseradish peroxidase.

The axoplasm of nodes of Ranvier in feline lumbosacral ventral spinal roots was analysed by light and electron microscopy 18-168 h after the injection of horseradish peroxidase (HRP) into the medial gastrocnemius muscle. Three main HRP distribution patterns were distinguished at PNS nodes (bordered by Schwann cells only) of large fibres transporting HRP. The type A pattern, characterized by a distal accumulation of HRP-positive bodies and a proximal system of vesiculotubular membrane profiles. The incidence of this type of node was highest at relatively short survival times. The type B pattern, which appeared somewhat later, resembled the type A node with the addition of a disc-like, proximal accumulation of HRP activity. The type C pattern which contained scattered HRP-positive bodies and delicate strands of membraneous profiles, dominated 72 h after injection. The number of HRP-positive PNS-CNS borderline nodes (bordered by both Schwann cells and glial cells) was less than 5% of the corresponding value in the same fibres of the ventral root proper. A highly segregated state of the axoplasm of PNS-CNS borderline nodes was noted only in two cases. The observations indicate a functional difference between nodal axoplasm at the PNS-CNS borderline and nodal axoplasm in the PNS part of the alpha motor neuron.

Electron microscopic cytochemistry of alkaline phosphatase in neurons of rats.

Fine structural localization of alkaline phosphatase activity was studied in the neurons of the cerebral cortex and the optics and sciatic nerves of the rat by electron microscopic histochemistry with the lead citrate method. Most neurons in the cerebral cortex demonstrated alkaline phosphatase activity on the plasma membrane of the nerve cell body and dendritic processes, from the thick trunk to the terminal postsynaptic boutons. Alkaline phosphatase was also associated with the axolemma, but only at the terminal presynaptic boutons and at the nodal and paranodal region of the nodes of Ranvier. The axolemma covered by myelin sheaths did not show any activity. The alkaline phosphatase reaction of the Ranvier node could also be demonstrated in the optic and sciatic nerves.

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.