The Effect of the Mouse Mutation Claw Paw on Myelination and Nodal Frequency in Sciatic Nerves

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The Journal of Neuroscience, August 1, 1998, 18(15):5859-5868

The Effect of the Mouse Mutation Claw Paw on Myelination and Nodal Frequency in Sciatic Nerves
Adam G. Koszowski¹, Geoffrey C. Owens²^,³, and S. Rock Levinson¹^,³
Departments of ¹ Physiology and Biophysics and ² Biochemistry and Molecular Genetics and ³ Program in Neuroscience, University of Colorado Health Sciences Center, Denver, Colorado 80262

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Despite the biophysical and clinical importance of differentiating nodal and internodal axolemma, very little is known aboutthe process. We chose to study myelination and node of Ranvierformation in the hypomyelinating mouse mutant claw paw (clp).The phenotype of clp is delayed myelination in the peripheralnervous system. The specific defect is unknown but is thoughtto arise from a breakdown in the complex signaling mechanism betweenaxon and Schwann cell. Myelination was assessed in sciatic nervecross sections from adult and postnatal day 14 (P14) heterozygousand homozygous clp mice. Antibodies to P0, myelin-associated glycoprotein(MAG), and neural cell adhesion molecule were used to assess thestage of myelination. P14 homozygous clp mice showed an atypicalstaining pattern of immature myelin, which resolved into a relativelynormal pattern by adulthood. Sodium channel clustering and nodeof Ranvier frequency were studied in whole-mount sciatic nerveswith sodium channel and MAG antibodies. P14 homozygous clp nervesagain showed an atypical, immature pattern with diffuse sodiumchannel clusters suggesting nodal formation was delayed. In theadult, homozygous clp sciatic nerves displayed dramatically shortenedinternodal distances. The data from this study support the hypothesesthat node of Ranvier formation begins with the onset of myelinationand that the number and location of nodes of Ranvier in the sciaticnerve are determined by myelinating Schwann cells.

Key words: internodal length; claw paw; sciatic nerve; node of Ranvier; sodium channel; immunocytochemistry; MAG; NCAM; P0

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

An alternating pattern of myelinating glia and nodal architecture is required for saltatory conduction in myelinated nerves.The key functional elements in this nodal architecture are voltage-gatedsodium channels, which are highly concentrated at nodes of Ranvierbut are diffuse along internodal axolemma. The means by whichnodal and internodal axolemma are differentiated, however, remainsto be discerned. It is generally agreed that a molecular dialoguemust take place between the neuron and glia for normal nodal development,and there has been a lot of interest in the details of this axon-gliainteraction (for review, see Salzer, 1997). An important questionabout this interaction concerns whether the location of nodesis determined by neurons or myelinating glia.

Several investigators have examined this question with conflicting results. Sodium channel distribution was examined immunocytochemicallyin normal rat sciatic nerves during development (Vabnick et al.,1996) and during remyelination (Dugandzija-Novakovic et al., 1995).In both cases, axonal sodium channel clusters were found at theends of Schwann cells that had just started myelinating, and theclusters seemed to get "pushed" by these elongating Schwann cellsuntil stable nodal gaps were formed by adjacent Schwann cells.These observations are strong evidence that myelinating Schwanncells determine the location of nodes of Ranvier in the peripheralnervous system (PNS).

The alternate hypothesis that axons predetermine nodal sites has support in a study of sodium channel distribution in culturedretinal ganglion cells (Kaplan et al., 1997). This study showedthat sodium channels could be organized along neuronal processesinto node-like clusters at the expected spatial frequency withonly cell-free, oligodendrocyte-conditioned media. This observationsuggests that neurons determine the location of nodes on CNS axons.Support for this hypothesis in the PNS has come from two studies.Deerinck et al. (1997) studied sodium channel distribution inspinal roots of dystrophic mice. These roots have fiber bundlesthat are devoid of Schwann cells, yet irregularly spaced sodiumchannel clusters were found on bare axolemma. Furthermore, Lambertet al. (1997) found that in developing rodent sciatic nerves,ankyrin-binding proteins were clustered at sites independent ofmyelinating Schwann cells.

In a further attempt to shed some light on the question of which cell type determines the location of nodes of Ranvier inPNS neurons, we chose to study the hypomyelinating mouse mutantclaw paw (clp). clp is an autosomal recessive mutation of an unknowngene resulting in a delay in the onset of myelination in the PNSwith no obvious ultrastructural axonal abnormalities or evidenceof ongoing demyelination and remyelination (Henry et al., 1991).It is hypothesized that this delay is attributed to a breakdownin the complex signaling mechanism between axon and Schwann cell.If this interaction were required for the specification of nodalsites, then one would expect nodal location to be altered temporallyand spatially in clp nerves. Thus, we examined the frequency ofnodes and the expression of myelin markers in sciatic nerves fromclp mice.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Mouse breeding
Six heterozygote clp/C57BL mice, obtained from The Jackson Laboratory (Bar Harbor, ME), were bred, and the progeny were screenedfor homozygotes. clp homozygotes were identified within 2 d ofbirth by the characteristic retracted forelimbs (Henry et al.,1991). Heterozygotes were generated by breeding homozygous clpfemales with wild-type C57BL/6 males.

Sciatic nerve immunocytochemistry
Antibody and general immunocytochemistry. The following primary antibodies were used in this study: anti-myelin associatedglycoprotein (MAG), monoclonal cell line 513 from mouse (BoehringerMannheim, Indianapolis, IN), anti-neural cell adhesion molecule(NCAM), monoclonal cell line H28 from rat (Boehringer Mannheim),anti-P0, polyclonal from rabbit (from Jeremy Brockes, Ludwig Institutefor Cancer Research), anti-sodium channel, and AP-1380-3.1 polyclonalfrom rabbit (peptide antigen, TEEQKKYYNAMKKLGSKK; Dugandzija-Novakovicet al., 1995). Secondary antibodies used in this study were donkeyanti-rabbit lissamine-rhodamine (Jackson ImmunoResearch, WestGrove, PA), goat anti-rat FITC (Jackson ImmunoResearch), and donkeyanti-mouse FITC (Jackson ImmunoResearch). All washes were performedin PBS, and incubations were done at room temperature unless otherwisenoted. Slides were mounted with Vectastain photoprotecting media(Vector Laboratories, Burlingame, CA), and all data collectionwas performed on a Bio-Rad (Hercules, CA) laser scanning confocalmicroscope (MRC-600). Digital images were reproduced on an EastmanKodak (Rochester, NY) 8650 dye sublimation printer.
Cross-sections. Mice were anesthetized with halothane and decapitated. Both sciatic nerves were removed at the level of thefemur and flash frozen in OCT. Ten-micrometer serial cryostatsections were collected onto Superfrost Plus glass slides (FisherScientific, Pittsburgh, PA) and allowed to dry. Slides were storedat $-$ 20°C until they were processed for immunocytochemistry. Theslides were thawed, and then one of two different immunostainingprotocols was used depending on the primary antibody. Sectionsto be stained with the anti-NCAM monoclonal antibody were thawedand fixed with 3.7% formaldehyde in 0.12 M sucrose in PBS. Theslides were then washed and placed in a humidified incubationchamber. Nonspecific protein binding sites were blocked, and thetissue was permeabilized with a blocking solution consisting of4% normal donkey serum, 2% bovine $gamma$ -globulin, and 0.4% TritonX-100 in PBS (BS+T). Primary antibodies (anti-NCAM at 1:100 andanti-P0 at 1:200) were diluted in BS+T and allowed to react overnight.Slides were washed again, and secondary antibodies were dilutedin BS+T, filtered, and applied. After washing, slides were rinsedin distilled water and mounted. Sections to be stained with theanti-MAG monoclonal antibody were thawed and fixed with 3.7% formaldehydein 0.12 M sucrose in PBS. The slides were then washed, permeabilizedwith 100% methanol, washed again, and then placed in a humidifiedincubation chamber. Nonspecific protein binding sites were blockedwith a blocking solution consisting of 12% normal donkey and goatserum in PBS (BS $-$ T) for at least 1 hr. Primary antibodies (anti-MAGat 1:20 and anti-P0 at 1:200) were diluted in BS $-$ T and allowedto react overnight. Slides were washed again, and secondary antibodieswere diluted in BS $-$ T, filtered, and applied to the slides. Afterwashing in PBS, slides were rinsed in distilled water and mounted.
Whole mounts. Mice were anesthetized with halothane and decapitated. Both sciatic nerves were removed at the level of thefemur and fixed for 30 min in 4% paraformaldehyde in PBS. Afterrinsing in 50% PBS, ~3 mm lengths of nerve were teased onto FisherSuperfrost Plus glass slides and allowed to dry. Slides were storedat $-$ 20°C until they were processed for immunocytochemistry. Theslides were thawed, rinsed, and placed in a humidified incubationchamber. Nonspecific protein binding sites were blocked, and thetissue was permeabilized with BS+T for at least 1 hr. Primaryantibodies were diluted in BS+T and allowed to react overnight.The sodium channel polyclonal antibody (AP-1380-3.1) and its blockedcontrol were used at 1:100. Blocking of the sodium channel antibodywas achieved by incubating 5 µl of undiluted antibody with 1 µlof its peptide antigen overnight at 4°C or for 4 hr at room temperature.The anti-MAG monoclonal antibody was used at 1:10. Slides werewashed again, and secondary antibodies were diluted in BS+T, filtered,and applied. After washing in PBS, slides were rinsed in distilledwater and mounted.

Internodal length measurement
Conventional. After sodium channel immunocytochemistry on whole-mount sciatic nerves, as described above, the Bio-Rad confocalmicroscope program COMOS scale bar was used to measure node-to-nodedistances from a randomly selected pool of fibers in single imagesor montages.
Statistical. After double staining whole-mount sciatic nerves for sodium channels and MAG, as described above, positive MAGimmunoreactivity was used to confirm that the fiber of interestwas myelinated. Individual myelinated fibers that could be followedfor >400 µm were measured. The number of nodes for that lengthwas counted. Individual measurements were then summed, and dividingthe number of nodes by total fiber length gave the nodal frequency,whose inverse is the mean internodal length. Fiber diameters weremeasured with the COMOS scale bar at a point just adjacent tothe nodal swelling. Errors attributed to the stochastic natureof nodal occurrence were calculated using Poisson statistics inwhich the coefficient of variation was the inverse of the squareroot of the number of nodes counted. Errors attributed to lengthmeasurement were found to be relatively insignificant and havebeen ignored.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Myelin marker immunostaining of sciatic nerve cross-sections

Adult heterozygotes
Immunostaining for P0 in sciatic nerve cross-sections from adult heterozygous animals showed the expected ring-like patternof bright-staining compact myelin around dark axoplasm (Fig. 1A)(Sternberger et al., 1979). Lawns of rings were interrupted bylarge areas with no P0-positive staining, presumably representinglarge bundles of unmyelinated fibers. These bundles stained withan antibody to NCAM, a marker present only on unmyelinated fibers(Martini and Schachner, 1986). A representative NCAM field isshown in Figure 1E, in which the irregular bright patches reflectbundles of unmyelinated nerve fibers. Adult heterozygote sciaticnerve cross-sections were also stained with a monoclonal antibodyagainst MAG. MAG staining was localized to the periaxonal uncompactedmyelin in myelinated fibers (Fig. 1C), as seen in the small ringsdistributed throughout the section. Double labeling with P0 andMAG confirmed that there was an outer P0-positive ring of compactmyelin and an inner MAG-positive ring of uncompacted myelin (datanot shown).

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Figure 1. Adult sciatic nerve cross-sections. P0, MAG, and NCAM immunostaining of cross-sectioned sciatic nerves from heterozygous (A, C, E) and homozygous (B, D, F) adult mice is shown. Note a similar staining pattern is seen in heterozygote and homozygote with P0 (A, B) and MAG (C, D). NCAM gives a slightly different pattern in the homozygote (F) than in the heterozygote (E). Ten-micrometer cryostat sections; scale bar, 50 µm.

Adult homozygotes
Adult homozygous clp sciatic nerve cross-sections showed a staining pattern with both P0 and MAG that was very similar (exceptfor the dark areas, see below) to that of nerve sections fromheterozygotes (Fig. 1B,D). NCAM immunoreactivity, however, appeareddifferent in the clp nerves (Fig. 1F). NCAM-positive stainingwas still present in unmyelinated fiber bundles but appeared tobe associated with smaller bundles in the mutant compared withthe heterozygote (Fig. 1, compare F, E). This observation wasconfirmed in the P0-stained sections by noting that the regionsfree of P0 were larger in the heterozygote than the homozygote(Fig. 1, compare A, B). Smaller NCAM bundles in the homozygotesuggests that clp may have an altered time course of fiber sorting(i.e., fasciculation).

P14 heterozygotes
Nerves from P14 heterozygotes stained with P0 resembled their adult counterparts, showing relatively uniform staining of myelinatednerves as rings throughout the section (Fig. 2A). Likewise, theMAG staining (Fig. 2C) and NCAM staining (Fig. 2E) in the P14heterozygote mirrored the staining pattern in the adult heterozygote.These observations suggest that in the heterozygote myelinationis nearly complete by P14. The only difference observed betweenthe P14 and adult heterozygote sections was one of size, becauseP14 sciatic nerves were smaller than adult sciatic nerves.

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Figure 2. P14 sciatic nerve cross-sections. P0, MAG, and NCAM immunostaining of cross-sectioned sciatic nerves from heterozygous (A, C, E) and homozygous (B, D, F) 14-d-old mice is shown. Note that there are differences in each set of panels between the heterozygote and the homozygote. P14 homozygote has less P0 (A vs B) and less MAG (C vs D),but more NCAM (E vs F) than the P14 heterozygote. Arrows in B and D mark corresponding regions. Ten-micrometer cryostat sections; scale bar, 50 µm.

P14 homozygotes
In contrast to the heterozygote, the pattern of P0, MAG, and NCAM staining in the P14 homozygote suggested that myelinationwas still in the initial stages. P0 and MAG, for example, werepresent only in a small number of fibers (Fig. 2B,D). More specifically,MAG was present in the same P0-positive fibers and a few additionalfibers, as seen when sections were costained for P0 and MAG. Thus,in Figure 2, B and D are the same section costained for P0 andMAG and visualized with different fluorophore-labeled secondaryantibodies. Notice the central region of Figure 2D in which thereare some MAG-positive fibers that are not P0-positive (arrows).This observation shows that MAG is expressed during the earlystages of myelin wrapping before compaction in the clp homozygote.On the other hand, a higher level of NCAM immunoreactivity (Fig.2F) was seen throughout the section compared with the heterozygote(Fig. 2E), suggesting that most of the nerve fibers in the P14clp were still in a premyelinated state.
Overall, the above results strongly suggest that myelination is delayed in sciatic nerves from clp homozygotes. The next questionwas whether the myelination delay affected the relative locationof nodes of Ranvier. Whole mounts of sciatic nerve were used ratherthan cross-sections so that nodes could be more easily observedand internodal lengths could be measured.

Sodium channel immunostaining of sciatic nerve whole mounts

P14 heterozygotes
P14 sciatic nerve whole mounts were costained with our sodium channel polyclonal antibody and an anti-MAG monoclonal antibody(see Materials and Methods). The P14 heterozygote had the expectedpattern for mature myelin. MAG was restricted to Schmidt-Lantermanincisures and paranodes (Fig. 3C). Sodium channels were foundat nodes of Ranvier, identified by concentrated sodium channelstaining (arrows) and MAG-positive paranodes. Sodium channelswere also found diffusely distributed along unmyelinated fiberbundles (Fig. 3A, open arrows). These staining patterns supportthe data from cross-sections showing that myelination and nodeformation appear to be complete by P14 in the heterozygote.

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Figure 3. P14 sciatic nerve whole mounts. Sodium channel and MAG coimmunostaining of whole-mount sciatic nerves from heterozygous (A, C) and homozygous (B, D) P14 mice is shown. Insets are higher-magnification views of areas within the panels. E and G are heterozygote and F and H are homozygote sciatic nerves costained with MAG and the sodium channel antibody that had been preabsorbed with its peptide antigen. Arrows point to nodes of Ranvier and the corresponding locations in MAG-stained fields. Open arrows point to unmyelinated fibers and their corresponding locations in MAG stained fields. Scale bar, 50 µm.

P14 homozygotes
Figure 3B shows that there are sodium channel clusters (arrows); however, they are more diffuse than nodes in the heterozygote.By correlating with MAG staining (Fig. 3D), these sodium channelaggregations appear to be localized to the ends of myelinatingSchwann cells. In Figure 3, comparing B and D also shows thatthere were no sodium channel clusters other than those associatedwith MAG-positive Schwann cells, and low-level linear sodium channelstaining occurred in some regions where there were no MAG-positivefibers (open arrows). Fibers that had no MAG staining were unmyelinatedaxons that may or may not become myelinated later. The stage ofthe myelin present in P14 homozygote fibers could be assessedby the pattern of MAG immunoreactivity. Figure 3, D and H, showsthat MAG was expressed linearly along the Schwann cell length,which is a hallmark of precompacted early myelin (contrast thelinear MAG staining pattern of the homozygote with the maturemyelin pattern of MAG-positive paranodes and Schmidt-Lantermanincisures; Fig. 3C).
Figure 3, E and F, shows controls for the sodium channel antibody specificity. Figure 3E is a P14 heterozygote nerve costainedjust as in Figure 3A; however, the sodium channel antibody hasbeen preincubated with its peptide antigen. Blocked and unblockeddigital images (Fig. 3A,E) were treated identically. Figure 3Gis the corresponding MAG-stained image showing several paranodalregions with no specific nodal sodium channel staining in Figure3E above. Figure 3, F and H, shows a pair of blocked sodium channeland MAG antibody stainings of P14 homozygote nerves. Here, nosodium channel clusters are seen at the ends of MAG-positive Schwanncells, nor is there any linear sodium channel staining in regionswithout MAG.

Adult heterozygotes
These fibers were costained as before with sodium channel and MAG antibodies. Figure 4 shows four different fields of sodiumchannel immunocytochemistry of adult heterozygote sciatic nerves.Arrows denote nodes of Ranvier used to measure the internodallength. Figure 4A-C gives node-to-node measurements of internodallength. Figure 4D shows an example of a broken fiber, which presentsa problem in the use of node-to-node measurements that is addressedbelow.

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Figure 4. Adult heterozygote sciatic nerve whole mounts. Sodium channel immunoreactivity of whole-mount sciatic nerves from heterozygous adult mice is shown. Arrows point to nodes of Ranvier; internodal lengths measured between arrows in A-C are given. In D, the distance from the marked node to the break is given. Scale bar, 100 µm.

Adult homozygotes
Figure 5 has four different fields showing sodium channel immunocytochemistry in adult homozygote sciatic nerves. Arrows againdenote nodes of Ranvier used to measure internodal length, withthose distances given. Comparing Figures 4 and 5, one can seereadily that the homozygote appears to have shorter internodesthan the heterozygote in the examples given. In the next section,these and similar data are quantitated.

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Figure 5. Adult homozygote sciatic nerve whole mounts. Sodium channel immunoreactivity of whole-mount sciatic nerves from homozygous adult mice is shown. Arrows point to nodes of Ranvier; internodal lengths measured between arrows in A-D are given. Scale bar, 100 µm.

Internodal distance estimates through measurement of nodal spatial frequency

Quantitation of the homozygote internodal distance using node-to-node measurements was straightforward, because complete internodeswere present on most fibers imaged. The heterozygote proved tobe more challenging because of the much longer internodal distances,which made following an intact fiber from one node to the nextdifficult. As shown in Figure 4D the nerve fibers often brokebefore a second node was seen, and broken fibers could not beincluded in the node-to-node measurement data shown in Table 1.Excluding these data biases the internodal measurements to theshorter, measurable internodes only. In an attempt to obtain amore accurate reflection of the true internodal lengths, a statisticaltechnique was used. Individual myelinated fibers were followedas far as possible, and the total number of nodes was counted.MAG costaining was used to help identify nodes of Ranvier andmyelinated fibers. Table 2 shows the measurements and calculatedinternodal lengths for adult heterozygote and homozygote nerves.Using nodal frequency to determine internodal length revealeda larger difference between heterozygote and homozygote internodesthan node-to-node measurements, as expected from the bias effectdiscussed above (compare Tables 1, 2).


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Table 1. Mean internodal lengths from node-to-node measurements of adult heterozygote and homozygote whole-mount sciatic nerves


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Table 2. Mean internodal length calculations from nodal frequencies of adult heterozygote and homozygote whole-mount sciatic nerves

It was next considered whether this internodal length difference could be explained by changes in fiber diameter. Internodallength varies with fiber diameter and has been shown to be ~100times total fiber thickness (Waxman, 1978). To determine whetherabnormal clp homozygote internodal lengths were caused by an alteredfiber diameter profile or nonrandom selection of nerve fibers,fiber diameter was measured along with nodal frequency. Wild-typenerves were also analyzed to ensure that possible semidominantexpression of the clp mutation was not affecting the results (Henryet al., 1991).

Mean internodal length increased significantly with fiber diameter for the heterozygote and the wild type but not the homozygote(Fig. 6). Also analyzed were the number and percentage of fibersmeasured for each fiber diameter (Table 3). For example, fourhomozygote fibers were measured that had a diameter of 2 µm anda mean internodal length of 263 µm. These four 2 µm fibers represent5% of the total fibers measured of all diameters in the homozygote.From the results obtained, it was concluded that all of the fiberdiameters were represented in all three groups and that fiberselection was random. There does seem to be fewer of the largestfibers (> 10 µm) in the homozygote than in the wild type, butthis is most likely attributed to hypomyelination, because theoriginal study found no evidence for any other axonal abnormalities(Henry et al., 1991). Thus, the decreased internodal distanceobserved in clp appears to result solely from the effects of thedelayed myelination phenotype.

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Figure 6. Histogram of fiber diameter versus internodal length for homozygote, heterozygote, and wild-type sciatic nerve whole mounts.


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Table 3. Mean internodal length, number, and percentage of fibers studied for each fiber diameter in adult homozygote, heterozygote, and wild-type whole-mount sciatic nerves

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Myelin marker staining of sciatic nerve cross-sections from heterozygous and homozygous mice gave the pattern one might expectfor a recessive, delayed myelination mutant. The P14 heterozygotefiber staining showed a normal distribution of all three fibermarkers studied. Using the P14 heterozygote as a basis for comparison,the P14 homozygote cross-sections had an abnormal appearance;both MAG and P0 immunoreactivities were decreased, whereas NCAMstaining was increased. This observation suggests that most ofthe fibers in the P14 homozygote were stalled in an unmyelinatedstage, with relatively few fibers going through the process ofmyelination. Once initiated, the myelination process itself appearedto be unaffected by the clp mutation, because all three fibermarkers were in their proper location and sequence. Notably, MAGexpression preceded P0 expression in clp myelination just as inwild type (Martini et al., 1988; Owens and Bunge, 1989).

Sodium channel and MAG staining in P14 sciatic nerve whole mounts corroborated the results from cross-sections. The P14 heterozygotehad a mature staining pattern with MAG and sodium channel antibodies.The MAG staining pattern of the P14 homozygote showed that myelinationwas still in its early stages, with very few Schwann cells stainingfor MAG. Those Schwann cells that were MAG-positive were typicallyisolated and expressed MAG in a linear manner. When colabeled,the sodium channels were found in diffuse clusters at the endsof the MAG-positive Schwann cells and distributed throughout someof the MAG-negative regions. All of the fiber-related sodium channelclusters found were in proximity to a MAG-positive Schwann cell.

These results are very similar to those reported in studies of sodium channel distribution in the developing and remyelinatingrat sciatic nerve. Using lysolecithin-induced demyelination, itwas found that sodium channel clusters appeared near the endsof adhering Schwann cells and were inferred to move with the Schwanncell during elongation until adjacent clusters fused into a maturenode of Ranvier (Dugandzija-Novakovic et al., 1995; Novakovicet al., 1996). In developmental studies, sodium channel clusterswere again found at the edges of Schwann cells determined to bein the early stages of myelination because of linear MAG staining(Vabnick et al., 1996). All axon-related sodium channel clusterswere found in proximity to a MAG-positive Schwann cell. The strikingsimilarity between these results and our studies of mouse clpsciatic nerves supports the hypothesis that myelinating Schwanncells determine the position of nodes of Ranvier.

Further support for this hypothesis was found when we analyzed adult clp sciatic nerve internodal lengths. Homozygous micehad dramatically shortened internodal lengths. However, the magnitudeof the difference between the heterozygote and homozygote dependedon the data collection technique. Node-to-node measurement datayielded a shorter internodal length for the heterozygote; however,it agreed well with previous work. Friede and Beuche (1985) useda similar technique from the same region of mouse sciatic nerveand reported an average internodal length of 693 ± 124 µm, comparedwith our measurement of 647 ± 203 µm. By calculating mean internodallength from total fiber length and total number of nodes counted,broken fibers could be included in the data, yielding 940 ± 90µm for the heterozygote.

There are several assumptions made when using this statistical technique. The first is that fiber breakage occurred in randomlocations. This assumption may not be entirely valid, becausefibers may have a tendency to break at nodes of Ranvier becausethere is no myelin there (see Figs. 4D, 5B). However, this nonrandombreakage is not a problem as long as the likelihood of leavingthe nodal axolemma itself on the slide to be counted is random.A second assumption made is that the fibers selected were a randomsample of the population, especially in terms of fiber diameter.If larger-diameter fibers were more likely to separate as individualfibers or less likely to break, then this might bias the results.Thus, fiber diameters were measured along with total fiber lengthand number of nodes, showing that there was no significant biasand that a representative fiber population had been selected.

Regardless of the method used, we observed that clp mice had dramatically shorter internodal lengths than their heterozygotecounterparts. What is the significance of altered internodal lengthto questions about nodal specification? Internodal length is theratio of axon length to the number of myelinating Schwann cells.In development, the axon continues to extend after it becomesmyelinated. It is thought that existing myelinating Schwann cellselongate with the growing axon; therefore, internodal distancesincrease until maturity (Schlaepfer and Myers, 1973; Friede etal., 1981). On the other hand, short internodal lengths occurin situations in which axon length is fixed, such as in the remyelinationof a denuded adult axon. We suggest that shortened internodallengths in clp peripheral nerves occurs as a result of the sameprocess that causes shortened internodal lengths after demyelination:limited axonal growth after a delayed initiation of myelination.Overall, shortened internodes after remyelination and observationsof sodium channel clustering at the edges of myelinating Schwanncells at all phases of elongation suggest that myelinating Schwanncells determine the location of new nodes of Ranvier.

A caveat when studying remyelination is that there is loss of the original nodes, which may reset or change the system insome way. Demyelination is known to upregulate sodium channelnumbers, and it is possible that these new channels are localizeddifferently than the original, developmental channels (Englandet al., 1991). However, clp appears to have the same net resultof shortened internodes without having a demyelinating stimulusor loss of original nodes. If axons alone specified nodal location,then one would expect a normal internodal length for the originalnodes. Thus, shortened internodes in clp also support the hypothesisthat myelinating Schwann cells determine the sites of nodes ofRanvier because the clp internodal distance seems to be dependenton Schwann cell growth and independent of intrinsic axon-relatedfactors such as fiber diameter or length.

In contrast, the alternate hypothesis of axonal predetermination of nodal sites seems to require less parsimonious explanationsof the findings presented here. To maintain this as a viable hypothesis,one must account for how the clp mutation simultaneously affectsthe independent processes of nodal site specification and myelinationas postulated by this paradigm. There are two possibilities bywhich this might occur. First, the clp defect might involve asingle gene product that lies at or upstream of a branch pointin a hypothetical cascade of molecular events that coordinatelyinitiates myelination and nodal site formation. Alternatively,clp could involve two distinct but genetically linked defectsthat separately affect myelination and nodal site formation. Regardlessof such considerations, it would seem that characterization ofthe molecular basis for the clp defect would yield important informationabout the early steps in PNS myelination and nodal formation.

There are cases in the PNS in which sodium channel clusters are found in the absence of Schwann cells. In all of these casesthere is a state of chronic demyelination. Sodium channels inchronic demyelination appear to redistribute differently thanin acute demyelination (England et al., 1996). These chronicallydemyelinated fibers may be able to make use of axonally specifiedankyrin-binding proteins (Lambert et al., 1997) to form node-likestructures. Myelinating Schwann cells, however, appear to havethe ability to reorganize these binding protein clusters alongwith ankyrin and sodium channels $---$ just the properties that cellswould need to specify nodes of Ranvier.

Some questions that remain unanswered about this study revolve around the nature of the clp defect. The defect appears toinvolve the early interaction of Schwann cells and axons, so likelycandidate proteins would be adhesion molecules such as MAG, NCAM,and L1. The MAG gene is located near the clp mutation on chromosome7 (Barton et al., 1987; Henry et al., 1991); however, the correctpositional and sequential expression of MAG suggests that theprimary defect in clp is not in the coding region of the MAG geneitself. This hypothesis has been confirmed in a breeding experimentin which a MAG knock-out mouse was crossed with a clp homozygotemouse. If the clp mutation was not allelic to the MAG locus, thennormal progeny would be expected because of complementation. Allof the progeny from this cross had normal forelimb posture andnormal MAG expression (G. C. Owens, C. Li, and J. R. Roder, unpublishedobservations). The NCAM gene maps to chromosome 9, and its expressionpattern looks appropriate (D'Eustachio et al., 1985). L1 is X-linked,and its expression pattern was not studied (Djabali et al., 1990).The key to understanding the clp defect will be finding the mutatedgene and determining its function. If this can be done, then ourfindings suggest that further insight may be forthcoming intothe nature of axon-Schwann cell communication and its role innodal development.

  FOOTNOTES

Received Feb. 17, 1998; revised May 5, 1998; accepted May 12, 1998.

This work was supported by National Institutes of Health Grant NS34375. We thank Dr. Robin Michaels for assistance with cryostatsectioning, Dawn Hilton for care of the mice, and Dr. MargaretNeville for assistance with this manuscript.
Correspondence should be addressed to Adam Koszowski, 4200 East Ninth Avenue, Box C240, Denver, CO 80262.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Barton DE, Arquint M, Roder J, Dunn R, Francke U (1987) The myelin-associated glycoprotein gene: mapping to human chromosome 19 and mouse chromosome 7 and expression in quivering mice. Genomics 1:107-112[Medline].
D'Eustachio P, Owens GC, Edelman GM, Cunningham BA (1985) Chromosomal location of the gene encoding the neural cell adhesion molecule (N-CAM) in the mouse. Proc Natl Acad Sci USA 82:7631-7635[Abstract/Free Full Text].
Deerinck TJ, Levinson SR, Bennett GV, Ellisman MH (1997) Clustering of voltage-sensitive sodium channels on axons is independent of direct Schwann cell contact in the dystrophic mouse. J Neurosci 17:5080-5088[Abstract/Free Full Text].
Djabali M, Mattei MG, Nguyen C, Roux D, Demengeot J, Denizot F, Moos M, Schachner M, Goridis C, Jordan BR (1990) The gene encoding L1, a neural adhesion molecule of the immunoglobulin family, is located on the X chromosome in mouse and man. Genomics 7:587-593[Web of Science][Medline].
Dugandzija-Novakovic S, Koszowski AG, Levinson SR, Shrager P (1995) Clustering of Na⁺ channels and node of Ranvier formation in remyelinating axons. J Neurosci 15:492-503[Abstract].
England JD, Gamboni F, Levinson SR (1991) Increased numbers of sodium channels form along demyelinated axons. Brain Res 548:334-337[Web of Science][Medline].
England JD, Levinson SR, Shrager P (1996) Immunocytochemical investigations of sodium channels along nodal and internodal portions of demyelinated axons. Microsc Res Tech 34:445-451[Web of Science][Medline].
Friede RL, Beuche W (1985) A new approach toward analyzing peripheral nerve fiber populations. I. Variance in sheath thickness corresponds to different geometric proportions of the internodes. J Neuropathol Exp Neurol 44:60-72[Web of Science][Medline].
Friede RL, Meier T, Diem M (1981) How is the exact length of an internode determined? J Neurol Sci 50:217-228[Web of Science][Medline].
Henry EW, Eicher EM, Sidman RL (1991) The mouse mutation claw paw: forelimb deformity and delayed myelination throughout the peripheral nervous system. J Hered 82:287-294[Abstract/Free Full Text].
Kaplan MR, Meyer-Franke A, Lambert S, Bennett V, Duncan ID, Levinson SR, Barres BA (1997) Induction of sodium channel clustering by oligodendrocytes. Nature 386:724-728[Medline].
Lambert S, Davis JQ, Bennett V (1997) Morphogenesis of the node of Ranvier: coclusters of ankyrin and ankyrin-binding integral proteins define early developmental intermediates. J Neurosci 17:7025-7036[Abstract/Free Full Text].
Martini R, Schachner M (1986) Immunoelectron microscopic localization of neural cell adhesion molecules (L1, N-CAM, and MAG) and their shared carbohydrate epitope and myelin basic protein in developing sciatic nerve. J Cell Biol 103:2439-2448[Abstract/Free Full Text].
Martini R, Bollensen E, Schachner M (1988) Immunocytological localization of the major peripheral nervous system glycoprotein P0 and the L2/HNK-1 and L3 carbohydrate structures in developing and adult mouse sciatic nerve. Dev Biol 129:330-338[Web of Science][Medline].
Novakovic SD, Deerinck TJ, Levinson SR, Shrager P, Ellisman MH (1996) Clusters of axonal Na⁺ channels adjacent to remyelinating Schwann cells. J Neurocytol 25:403-412[Web of Science][Medline].
Owens GC, Bunge RP (1989) Evidence for an early role for myelin-associated glycoprotein in the process of myelination. Glia 2:119-128[Web of Science][Medline].
Salzer JL (1997) Clustering sodium channels at the node of Ranvier: close encounters of the axon-glia kind. Neuron 18:843-846[Web of Science][Medline].
Schlaepfer WW, Myers FK (1973) Relationship of myelin internode elongation and growth in the rat sural nerve. J Comp Neurol 147:255-266[Web of Science][Medline].
Sternberger NH, Quarles RH, Itoyama Y, Webster HD (1979) Myelin-associated glycoprotein demonstrated immunocytochemically in myelin and myelin-forming cells of developing rat. Proc Natl Acad Sci USA 76:1510-1514[Abstract/Free Full Text].
Vabnick I, Novakovic SD, Levinson SR, Schachner M, Shrager P (1996) The clustering of axonal sodium channels during development of the peripheral nervous system. J Neurosci 16:4914-4922[Abstract/Free Full Text].
Waxman SG (1978) Variations in axonal morphology and their functional significance. In: Physiology and pathobiology of axons (Waxman SG, ed), pp 169-190. New York: Raven.

Copyright © 1998 Society for Neuroscience 0270-6474/98/18155859-10$05.00/0

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