Detection of sodium channel distribution in rat sciatic nerve following lysophosphatidylcholine-induced demyelination

Lysophosphatidylcholine 16:0 mediates chronic joint pain associated to rheumatic diseases through acid-sensing ion channel 3

ABSTRACT

Rheumatic diseases are often associated to debilitating chronic pain, which remains difficult to treat and requires new therapeutic strategies. We had previously identified lysophosphatidylcholine (LPC) in the synovial fluids from few patients and shown its effect as a positive modulator of acid-sensing ion channel 3 (ASIC3) able to induce acute cutaneous pain in rodents. However, the possible involvement of LPC in chronic joint pain remained completely unknown. Here, we show, from 2 independent cohorts of patients with painful rheumatic diseases, that the synovial fluid levels of LPC are significantly elevated, especially the LPC16:0 species, compared with postmortem control subjects. Moreover, LPC16:0 levels correlated with pain outcomes in a cohort of osteoarthritis patients. However, LPC16:0 do not appear to be the hallmark of a particular joint disease because similar levels are found in the synovial fluids of a second cohort of patients with various rheumatic diseases. The mechanism of action was next explored by developing a pathology-derived rodent model. Intra-articular injections of LPC16:0 is a triggering factor of chronic joint pain in both male and female mice, ultimately leading to persistent pain and anxiety-like behaviors. All these effects are dependent on ASIC3 channels, which drive sufficient peripheral inputs to generate spinal sensitization processes. This study brings evidences from mouse and human supporting a role for LPC16:0 via ASIC3 channels in chronic pain arising from joints, with potential implications for pain management in osteoarthritis and possibly across other rheumatic diseases.

In vivo real-time dynamics of ATP and ROS production in axonal mitochondria show decoupling in mouse models of peripheral neuropathies

Mitochondria are critical for the function and maintenance of myelinated axons notably through Adenosine triphosphate (ATP) production. A direct by-product of this ATP production is reactive oxygen species (ROS), which are highly deleterious for neurons. While ATP shortage and ROS levels increase are involved in several neurodegenerative diseases, it is still unclear whether the real-time dynamics of both ATP and ROS production in axonal mitochondria are altered by axonal or demyelinating neuropathies. To answer this question, we imaged and quantified mitochondrial ATP and hydrogen peroxide (H2O2) in resting or stimulated peripheral nerve myelinated axons in vivo, using genetically-encoded fluorescent probes, two-photon time-lapse and CARS imaging. We found that ATP and H2O2 productions are intrinsically higher in nodes of Ranvier even in resting conditions. Axonal firing increased both ATP and H2O2 productions but with different dynamics: ROS production peaked shortly and transiently after the stimulation while ATP production increased gradually for a longer period of time. In neuropathic MFN2R94Q mice, mimicking Charcot-Marie-Tooth 2A disease, defective mitochondria failed to upregulate ATP production following axonal activity. However, elevated H2O2 production was largely sustained. Finally, inducing demyelination with lysophosphatidylcholine resulted in a reduced level of ATP while H2O2 level soared. Taken together, our results suggest that ATP and ROS productions are decoupled under neuropathic conditions, which may compromise axonal function and integrity.

Neuronal activity in the hub of extrasynaptic Schwann cell-axon interactions

The integrity and function of neurons depend on their continuous interactions with glial cells. In the peripheral nervous system glial functions are exerted by Schwann cells (SCs). SCs sense synaptic and extrasynaptic manifestations of action potential propagation and adapt their physiology to support neuronal activity. We review here existing literature data on extrasynaptic bidirectional axon-SC communication, focusing particularly on neuronal activity implications. To shed light on underlying mechanisms, we conduct a thorough analysis of microarray data from SC-rich mouse sciatic nerve at different developmental stages and in neuropathic models. We identify molecules that are potentially involved in SC detection of neuronal activity signals inducing subsequent glial responses. We further suggest that alterations in the activity-dependent axon-SC crosstalk impact on peripheral neuropathies. Together with previously reported data, these observations open new perspectives for deciphering glial mechanisms of neuronal function support.

Subcellular localization and PKC-dependent regulation of the human lysophospholipase A/acyl-protein thioesterase in WISH cells

Lysophospholipases play essential roles in keeping their multi-functional substrates, the lysophospholipids, at safe levels. Recently, a 25 kDa human lysophospholipase A (hLysoPLA I) that is highly conserved among rat, mouse, human and rabbit has been cloned, expressed and characterized and appears to hydrolyze only lysophospholipids among the various lipid substrates. Interestingly, this enzyme also displays acyl-protein thioesterase activity towards a G protein alpha subunit. To target the subcellular location of this hLysoPLA I, we have carried out immunocytochemical studies and report here that hLysoPLA I appears to be associated with the endoplasmic reticulum (ER) and nuclear envelope in human amnionic WISH cells and not the plasma membrane. In addition, we found that the hLysoPLA I can be up-regulated by phorbol 12-myristate 13-acetate (PMA) stimulation, a process in which phospholipase A(2) is activated and lysophospholipids are generated in WISH cells. Furthermore, the PMA-induced hLysoPLA I expression can be blocked by the protein kinase C (PKC) inhibitor Gö6976. The regulated expression of the LysoPLA/acyl-protein thioesterase by PKC may have important implications for signal transduction processes.

A specific human lysophospholipase: cDNA cloning, tissue distribution and kinetic characterization

Lysophospholipases are critical enzymes that act on biological membranes to regulate the multifunctional lysophospholipids; increased levels of lysophospholipids are associated with a host of diseases. Herein we report the cDNA cloning of a human brain 25 kDa lysophospholipid-specific lysophospholipase (hLysoPLA). The enzyme (at both mRNA and protein levels) is widely distributed in tissues, but with quite different abundances. The hLysoPLA hydrolyzes lysophosphatidylcholine in both monomeric and micellar forms, and exhibits apparent cooperativity and surface dilution kinetics, but not interfacial activation. Detailed kinetic analysis indicates that the hLysoPLA binds first to the micellar surface and then to the substrate presented on the surface. The kinetic parameters associated with this surface dilution kinetic model are reported, and it is concluded that hLysoPLA has a single substrate binding site and a surface recognition site. The apparent cooperativity observed is likely due to the change of substrate presentation. In contrast to many non-specific lipolytic enzymes that exhibit lysophospholipase activity, hLysoPLA hydrolyzes only lysophospholipids and has no other significant enzymatic activity. Of special interest, hLysoPLA does not act on plasmenylcholine. Of the several inhibitors tested, only methyl arachidonyl fluorophosphonate (MAFP) potently and irreversibly inhibits the enzymatic activity. The inhibition by MAFP is consistent with the catalytic mechanism proposed for the enzyme - a serine hydrolase with a catalytic triad composed of Ser-119, Asp-174 and His-208.

Abnormally large evoked potentials arising from dorsal column fibers in the region of chronically compressed spinal cord

OBJECTIVE

To understand the origin and mechanism of the large evoked potentials known to occur in chronically compressed spinal cord.

METHODS

Electrophysiological analysis was made of evoked potentials produced in the cervical cord compressed for more than 1 year by rotating a screw in the vertebral body, in 4 adult cats.

RESULTS

In all cats, manifesting no motor disturbance, large positive or negative evoked potentials were recorded from the cord dorsum at the compressed region following lumbar cord stimulation. These potentials followed high-frequency stimulation and were judged as conducting volleys of directly activated fibers. Intraspinally, single fiber spikes, normally barely recordable with the glass microelectrodes, were recorded extracellularly from localized areas within the dorsal column restricted to the compressed region. Such single fibers showed slowed conduction at the compressed region without a conduction block. Histologically, demyelinated fibers were observed in localized areas in the dorsal column of the compressed region.

CONCLUSION

We concluded that the large abnormal surface potentials originated from the dorsal column and were attributed to an increase in action current in affected fibers, which presumably occurred associated with demyelination.

A distributed-parameter model of the myelinated nerve fiber

This paper presents a new model for the characterization of electrical activity in the nodal, paranodal and internodal regions of isolated amphibian and mammalian myelinated nerve fibers. It differs from previous models in the following ways: (1) in its ability to incorporate detailed anatomical and electrophysiological data; (2) in its approach to the myelinated nerve fiber as a multi-axial cable; and (3) in the numerical algorithm used to obtain distributed model equation solutions for potential and current. The morphometric properties are taken from detailed electron microscopic anatomical studies (Berthold & Rydmark, 1983a, Experientia 39, 964-976). The internodal axolemma is characterized as an excitable membrane and model-generated nodal and internodal membrane action potentials are presented. A system of describing equations for the equivalent network model is derived, based on the application of Kirchoff's Current Law, which take the form of multiple cross-coupled parabolic partial differential equations. An implicit numerical integration method is developed and the numerical solution implemented on a parallel processor. Non-uniform spatial step sizes are used, enabling detailed representation of the nodal region while minimizing the number of total segments necessary to represent the overall fiber. Conduction velocities of 20.2 m sec-1 at 20 degrees C for a 15 microns diameter amphibian fiber and 57.6 m sec-1 at 37 degrees C for a 17.5 microns diameter mammalian fiber are achieved, which agrees qualitatively with published experimental data at similar temperatures (Huxley & Stämpfli, 1949, J. Physiol., Lond. 108, 315-339; Rasminsky, 1973, Arch, Neurol. 28, 287-292). The simulation results demonstrate the ability of this model to produce detailed representations of the transaxonal, transmyelin and transfiber potentials and currents, as well as the longitudinal extra-axonal, periaxonal and intra-axonal currents. Also indicated is the potential contribution of the paranodal axolemma to nodal activity as well as the presence of significant longitudinal currents in the periaxonal space adjacent to the node of Ranvier.

Colchicine prevents recovery of nerve conduction at chronic demyelination

A colchicine cuff was applied to rat sciatic nerve proximal to a demyelinating region produced by a focal injection of lysophosphatidylcholine (LPC). The colchicine cuff prevented the recovery of function normally seen within 6-8 days after LPC-induced demyelination. Colchicine blocked the delivery of sodium channels to the demyelinated region and induced their accumulation proximal to the cuff. The dual effect of colchicine in blocking both the recovery of impulse propagation through the demyelinated region and the delivery of sodium channels suggests a central role for fast axonal transport of sodium channels in the recovery of function at demyelination.

Differential expression of sodium channel mRNAs in rat peripheral nervous system and innervated tissues

RNA blot hybridization analyses using probes specific for sodium channels I, II and III revealed high levels of sodium channel I mRNA and low levels of sodium channel II and III mRNAs in peripheral nervous system (PNS) tissues. The developmental expression patterns of these mRNAs were generally similar to those described for the central nervous system. The small amounts of sodium channel I and III mRNAs present in tongue muscle were greatly reduced after partial denervation. Expression of the three sodium channels thus appears to be restricted to the nervous system. Putative novel additional mRNAs, specifically expressed in the PNS, were detected with a probe that recognizes nucleotide sequences common to sodium channels I, II and III.

Modification of the Na-dependent action potential in myelinated fibers of rat sciatic nerve exposed to phorbol ester

Exposure of rat sciatic nerve to the active phorbol 1,2-beta-myristate-13-acetate (b-PMA), but not to the active analogue 4-alpha-phorbol-12,13-didecanoate (a-PDD), is followed by a decrease of the compound action potential amplitude, rate of rise, and conduction velocity, and an increase of the threshold, and of the duration of the refractory period. The effect is concentration-dependent, the Kd being 250 nM. The attenuated Na-dependent action potential is tetrodotoxin (TTX)-sensitive, but after exposure to b-PMA the sensitivity to TTX is decreased from Kd = 45 nM to 400 nM. Action potential depression is larger when Ca is replaced by Mg (but not by Ba), or when Na is replaced by Li. The replacement of K by Cs, or exposure to potassium channel blockers such as 4-aminopyridine (4AP) and tetra-ethyl ammonium (TEA) has no effect. The results indicate that in the myelinated axons of rat sciatic nerve, exposure to b-PMA induces modification of Na channels.

The distribution of sodium and potassium channels in single demyelinated axons of the frog

1. Frog sciatic nerves were focally demyelinated by intraneural injection of lysolecithin. Fibres were examined 1-8 days later. At early times axons contained zones just a few micrometers long that were covered by myelin debris. These zones lengthened and the debris was cleared over the next several days. 2. The loose patch clamp technique was used to measure ionic currents in the demyelinated axolemma in both internodal and paranodal regions. 3. Transient inward currents that have been identified as Na+ currents on the basis of voltage dependence and sensitivity to tetrodotoxin were recorded at all stages tested. There was no significant increase in internodal peak Na+ current with time over the first 8 days after injection. 4. Peak inward currents varied relatively little with distance along the internode at 1 day post-injection. However, sharp gradients were detected at demyelinated paranodal and nodal membranes. 5. By combining the patch clamp with external stimulation proximal to the patch site it has been possible to record membrane current responses to propagating signals invading the demyelinated zone. With demyelination only in the distal heminode the extent of Na+ channel activation is similar to that predicted for normal nodes of Ranvier by Frankenhaeuser & Huxley (1964). 6. The ratio of K+ conductance to Na+ conductance is much higher in demyelinated internodes than in normal nodes of Ranvier. 7. It is concluded that Na+ channels are likely to be present in normal internodes. The total number of these internodal channels may be about 40 times the total number at nodes. Steep gradients of Na+ channel density remain at nodal regions at least up to 6 days following demyelination.

Distribution and possible abnormality in antigenic composition of sodium channels in peripheral axons of dystrophic mice

In some dystrophic mice (Bar-Harbour 129 dy/dy), axons of the sciatic nerve are a-myelinated but are capable of carrying action potentials. In this study, we showed by immunofluorescence that such excitability is supported by the presence of voltage-gated sodium channels along the a-myelinated axon. In addition, the number of sodium channels measured by radioimmunoassay in sciatic nerves of these dystrophic mice is significantly higher. Furthermore, the composition of sodium channel epitopes is abnormal. This suggested a link between the disease and the biogenesis of the sodium channels.