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Previous Article | Next Article
The Journal of Neuroscience, August 1, 2002, 22(15):6458-6470
Connexin29 Is Uniquely Distributed within Myelinating Glial Cells of the Central and Peripheral Nervous Systems
Bruce M. Altevogt2, Kleopas A. Kleopa3, Friso R. Postma1, Steven S. Scherer3, and David L. Paul1 1 Department of Neurobiology and 2 Program in Neuroscience, Harvard Medical School, Boston, Massachusetts 02115, and 3 Department of Neurology, The University of Pennsylvania Medical Center, Philadelphia, Pennsylvania 19104-6077
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Although both Schwann cells and oligodendrocytes express connexin32 (Cx32), the loss of this connexin causes demyelination only in the PNS. To determine whether oligodendrocytes might express another connexin that can function in place of Cx32, we searched for novel CNS-specific connexins using reverse transcriptase-PCR and degenerate primers. We identified Cx29, whose transcript was restricted to brain, spinal cord, and sciatic nerve. Developmental expression of Cx29 mRNA in the CNS paralleled that of other myelin-related mRNAs, including Cx32. In the CNS, Cx29 antibodies labeled the internodal and juxtaparanodal regions of small myelin sheaths, whereas Cx32 staining was restricted to large myelinated fibers. In the PNS, Cx29 expression preceded that of Cx32 and declined to lower levels than Cx32 in adulthood. In adult sciatic nerve, Cx29 was primarily localized to the innermost aspects of the myelin sheath, the paranode, the juxtaparanode, and the inner mesaxon. Cx29 displayed a striking coincidence with Kv1.2 K+ channels, which are localized in the axonal membrane. Both Cx29 and Cx32 were found in the incisures. Cx29 expressed in N2A cells did not induce intercellular conductances but did participate in the formation of active channels when coexpressed with Cx32. Together, these data show that Cx29 and Cx32 are expressed by myelinating glial cells with distinct distributions.
Key words: Gap junction; connexin; myelin; oligodendrocyte; Schwann cell; Cx29
INTRODUCTION
Gap junctional intercellular communication (GJIC) is commonly observed in glial cells. Its importance is underscored by the fact that mutations in the gap junction protein connexin32 (Cx32) cause a demyelinating peripheral neuropathy, X-linked Charcot-Marie-Tooth disease (CMTX) (Bergoffen et al., 1993
). Myelinating Schwann cells express Cx32, and the expression of Cx32 mRNA parallels that of other myelin genes, such as mpz (Scherer et al., 1995
A loss of reflexive coupling caused by cx32 mutations could underlie peripheral demyelination in CMTX. However, nerve conduction velocities in cx32-null mice are nearly normal, and compared with other animal models of inherited demyelinating neuropathy, demyelination begins rather late (Anzini et al., 1997
Multiple connexin expression could also explain why CMTX patients seldom have clinical CNS manifestations (Kleopa et al., 2002
With these issues in mind, we searched for novel connexins in the CNS, using reverse transcriptase (RT)-PCR and degenerate primers. We identified Cx29, whose transcript was restricted to brain, spinal cord, and sciatic nerve. In the spinal cord, Cx29 was primarily found in myelin sheaths surrounding small fibers, whereas Cx32 staining was primarily found in myelin sheaths surrounding large myelinated fibers. Myelinating Schwann cells expressed both connexins, but their intracellular localization was different. Cx29 was primarily localized to the innermost aspects of the myelin sheath, the paranode, juxtaparanode, and the inner mesaxon and displayed a striking coincidence with axonal Kv1.2 K+ channels. In contrast, Cx32 was primarily found in paranodes, whereas incisures contained both Cx29 and Cx32. Cx29 by itself did not induce GJIC in N2A cells; however, in combination with Cx32, it formed channels with novel properties.
MATERIALS AND METHODS
PCR and genomic cloning. Adult mouse brain cDNA was synthesized from total RNA extracted using TRIzol (Invitrogen, Gaithersburg, MD) and reverse transcribed with Superscript II RNase H-reverse transcriptase (Invitrogen). Two degenerate oligonucleotides were synthesized corresponding to the first and second extracellular loop of seven connexins expressed in the CNS (mCx26, hCx32, pCx34.7, pCx35, mCx36, mCx43, and mCx45). The upstream primer 5'-CA(GA)CC(TGAC)GG(CT)TG(TC)(AG)A(CGA)(AC)(AG)(TGC)G(TC)(CAT)TGC-3' was 13,824-fold degenerate. The downstream primer 5'-(AG)(GT)GAA(GCA)A(CT)(GTCA)GT(CT)TT(CT)TC(CGAT)GT(GA)GG-3' was 3072-fold degenerate. RT-PCR (Advantage II; Clontech, Cambridge, UK) was performed using the following conditions: 95°C for 5 min, 94°C for 15 sec, 55°C for 15 sec, and 72°C for 45 sec (10 cycles); 94°C for 15 sec, 43°C for 15 sec, and 72°C for 45 sec (30 cycles). RT-PCR products were separated on 1% agarose Tris-acetate-EDTA gel. Seven bands were individually purified (Qia-quick; Qiagen, Hilden, Germany) and subcloned into pCRII-TOPO (Invitrogen). Clones (672) were screened using PCR to eliminate colonies containing Cx32 or Cx43, leaving 448 clones that were screened for redundancy by restriction analysis with AluI (New England Biolabs, Beverly, MA). The remaining 101 clones were sequenced, yielding four copies of a 750 bp clone with significant homology to the connexin gene family.
To obtain the complete coding sequence of the putative connexin clone, a high-stringency screen was performed on a 129 SvEv genomic library (Stratagene, La Jolla, CA). The original 750 bp amplicon was radiolabeled with 32P by random priming (Roche Molecular Biochemicals, Hertforshire, UK). Hybridization and plaque isolation were performed as described previously (Haefliger et al., 1992
Tissue collection for Northern blot analysis and in situ hybridization. For Northern blot analysis, the sciatic nerves of anesthetized (50 mg/kg pentobarbital, i.p.), adult (10-13 weeks old) Sprague Dawley rats were exposed at the sciatic notch. Permanent axotomy was accomplished by doubly ligating nerves, transecting between the ligatures with iridectomy scissors, and suturing the two nerve stumps
1 cm apart. This technique prevents axonal regeneration to the distal nerve stump for
80°C. Unlesioned sciatic nerves and various brain regions were obtained from animals of different ages, from postnatal day 1 (P1) to P90. All animal protocols were approved by the Institutional Animal Care and Use Committee (IACUC) of The University of Pennsylvania.
Total RNA was isolated and RNA blots were performed as described previously (Scherer et al., 1995
For in situ hybridization (ISH), adult mice (age 3-6 months) were killed following IACUC guidelines. The brain and spinal cord were dissected and fixed for 1 hr at room temperature in 4% paraformaldehyde, rinsed with PBS, and cryoprotected overnight in 30% sucrose/PBS. Tissue was embedded in optimal cutting temperature (OCT; Tissue-Tek; Miles, Elkhart, IN), frozen, and sectioned at 12 µm. In situ hybridization was performed using digoxigenin-labeled riboprobes. To assure specificity, three different probes for Cx29 were used. The first was a full-length coding region probe with 53 bp 5' to the start and 97 bp 3' to the stop codon. To produce separate nonoverlapping probes, the original probe was digesting with HindIII, and the resulting fragments were subcloned into pBluescript SK (Stratagene). All three probes produced the same pattern of labeling. A full-length probe for rat PLP (Milner et al., 1985
Preparation of anti-Cx29 antibodies. A bacterial fusion protein containing glutathione S-transferase (GST) plus the C-terminal portion of Cx29 (amino acids 220-258) was produced using the vector pGEX-4T-3 as described previously (Jiang et al., 1994
Western blots. A positive control for Western blotting was obtained by transfection of COS cells. Construction of the expression vector and transfection are as described below in the section discussing Cx29 channel physiology, except that COS cells were used. After a 2 d incubation, transfected cells were trypsinized and washed three times with PBS. Cells from one confluent 36 mm dish were resuspended in 200 µl of 50 mM Tris, pH 7.6, 1% SDS, 0.017 mg/ml phenylmethylsulfonyl fluoride, 0.05 µl/mg Sigma Protease Inhibitor cocktail P8340, and 18.5 µl/ml di-isopropylfluorophosphate; sonicated; and combined with 3× SDS-PAGE loading buffer (150 mM Tris, pH 7.6, 6% SDS, 30% glycerol, 0.3% bromophenol blue, and 300 mM DTT).
After separation on 4-20% acrylamide gels, proteins were transferred at 100 V for 70 min in 1× transfer buffer (0.2% methanol, 2.5 mM Tris, and 19.2 M glycine) onto Protran nitrocellulose pore 0.45 µm (Schleicher and Schuell, Keene, NH), blocked for 1 hr at room temperature [5% dry milk, 1× Tris-buffered saline with 1% Tween 20 (TBST)], and blotted overnight at 4°C in affinity purified fusion protein anti-Cx29 (anti-Cx29 1:8, 5% dry milk, 1× TBST). Blots were washed three times for 3 min in 1× TBST, incubated in 1:3000 anti-rabbit HRP-conjugated secondary antibody (170-6515; Bio-Rad, Richmond, CA) (1% dry milk, 1× TBST) for 45 min at room temperature, and washed with 1× TBST three times for 3 min; antibody binding was detected using ESL (Amersham Biosciences, Arlington Heights, IL) according to the manufacturer's recommendations.
Immunohistochemistry. Unfixed mouse or rat sciatic nerves and spinal cords were embedded in OCT and immediately frozen in a dry ice acetone bath. These tissues were also embedded in OCT after brief fixation (30-60 min) in either freshly prepared 4% paraformaldehyde in 0.1 M phosphate buffer (PB), pH 7.4, or Zamboni's fixative (4% paraformaldehyde in 0.1 M PB plus 15% v/v saturated picric acid) (Zamboni and de Martino, 1967
Immuno-electron microscopy. In preliminary experiments, segments of adult rat sciatic nerves (~1 cm long) were fixed in either 4% paraformaldehyde and 0.1% glutaraldehyde (Mi et al., 1995
Based on these pilot experiments, we repeated the experiment with 0.5% glutaraldehyde fixation. After immunostaining, the teased fibers were fixed overnight in 3% glutaraldehyde in 0.1 M PB, rinsed, osmicated in 1% OsO4 (in 0.1 M PB) for 1 hr at room temperature, dehydrated in graded ethanols, infiltrated with Durcopan ACM resin, and placed between glass slides that had been treated with Liquid Release Agent (EMS, Ft. Washington, PA). After polymerization in a 60°C oven overnight, selected areas were trimmed and mounted on a Durcopan stub with cyanoacrylate adhesive. Semithin sections (0.5 µm thick) were mounted on glass slides and photographed without counterstaining. Thin sections (silver interference color) were mounted on one hole, formvar-coated grids (EMS) and photographed in a Zeiss (Thornwood, NY) EM10 electron microscope without counterstaining. Light microscopic images of the teased fibers and semithin sections were generated with a cooled Hamamatsu camera. Electron micrographs were printed and scanned; these images were imported into Adobe PhotoShop and assembled.
Cx29 channel physiology. To produce a construct for expression of Cx29 in Xenopus oocytes and N2A cells, the 16 kb genomic clone was digested with DraI and BsgRI, and the fragment was subcloned into the StuI site of pCS2+. In addition, rat Cx32 cDNA (Paul, 1986
Studies were also performed using dual whole-cell patch clamp in transiently transfected N2A cells. N2A neuroblastoma cells were grown in DMEM supplemented with 10% fetal calf serum. On reaching 80% cell density, cells were washed with DMEM/F-12 and transfected using lipofectamine (Invitrogen) according to the manufacturer's directions. Cells were transfected with either 1 µg of Cx29, 0.2 µg of Cx32, or both. Connexins were cotransfected with equivalent amounts of vectors expressing either enhanced green fluorescent protein (eGFP) or enhanced yellow fluorescent protein (eYFP) (Clontech) so that transfected cells could be identified for patch clamping. After transfection (12 hr), cells were trypsinized, mixed in a 1:1 ratio, and reseeded in low density. Recordings of green/yellow fluorescent cell pairs were routinely initiated after 3 hr.
Double patch-clamp recordings were performed as described by Srinivas et al. (1999)
(Sutter Instruments, Novato, CA) and filled with (in mM): 140 CsCl, 10 HEPES, 1 MgCl2, 5 EGTA, and 0.5 CaCl, pH 7.2. The extracellular solution contained (in mM): 140 NaCl, 10 HEPES, 2 CaCl2, 1 MgCl2, 5 CsCl, and 10 D-glucose, pH 7.4. Patch amplifiers (EPC-7; Heka Electronik, Lambrecht/Pfalz, Germany, and Axoclamp 200B; Axon Instruments, Union City, CA) were interfaced to a personal computer-running pClamp 8 via the digidata1200 (Axon Instruments). After obtaining G
RESULTS
Cloning of Cx29
PCR amplification of brain cDNA with degenerate primers for the two extracellular loops yielded seven distinct bands ranging in size from 200 to 750 bp (data not shown). Each band was separately gel purified and subcloned. Colonies (96) of each were screened to eliminate known connexins. The remaining 101 subclones were sequenced, yielding four identical copies of a 750 bp insert with significant homology to other connexins. To obtain the complete coding region, the 750 bp insert was used to screen a 129SvEv genomic DNA library (Stratagene). Sequence analysis of the genomic clone revealed an open reading frame of 777 bp (Fig. 1A), predicting a protein exhibiting features common to connexins, including four transmembrane domains and two extracellular domains with the characteristic three cysteine motif (White and Paul, 1999
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Figure 1. Cx29 is among the most divergent connexins. A, Alignment of Cx29 and hCx31.3 reveals 61% amino acid identity. Nonidentical residues are boxed. B, Dendrogram illustrating phylogenetic relationships based on CLUSTAL algorithm. These data suggest that Cx29 and hCx31.3 are orthologs and are among the most divergent members of the connexin family.
TblastN searches of the GenBank HTGS database using the mouse Cx29 sequence identified three human genomic segments. The connexin-related ORFs predicted by two of these (AC004977 and AC011904) were identical, whereas the other (AC004522) exhibited multiple stops and was likely a nonfunctional gene. The molecular mass of the connexin predicted by the first two was 30.31 kDa. This putative connexin was also described by Sohl et al. (2001)
Alignment of the Cx29 and hCx31.3 open reading frames revealed 61% identity. This high level of relatedness suggests that Cx29 and hCx31.1 are orthologs (Fig. 1A). As indicated by CLUSTAL analysis (Fig. 1B), Cx29 was more closely related to hCx31.3 than to any other murine connexin. The CLUSTAL algorithm also demonstrated that Cx29 and hCx31.3 were among the most divergent members of the connexin family. Although computer-aided analyses of connexin sequences suggest the grouping of connexins into subclasses (Sohl et al., 2001
Cx29 expression is restricted to the CNS and PNS and coordinately expressed with myelin genes
To determine which tissues express Cx29, Northern blot analysis was performed on total RNA extracted from adult mouse organs. Cx29 mRNA was detected in the brain, as expected, because it was cloned from brain cDNA and spinal cord (Fig. 2A). Cx29 mRNA was also found in sciatic nerve, at higher levels relative to brain or spinal cord (compare Cx29 and GAPDH signals). Cx29 mRNA was below the level of detection in the other tissues examined. Together, these data suggest that Cx29 may be a product of myelinating glial cells.
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Figure 2. Cx29 is a nervous system-specific connexin and is expressed coordinately with other myelin-related genes. Northern blots of total RNA were hybridized with the indicated cDNA probes. A, Cx29 transcript is detected only in brain, spinal cord, and sciatic nerve of adult mice. B, C, Developmental pattern of Cx29 mRNA expression in mouse cerebellum (B) and cerebrum (C) generally parallels that of PLP (only the largest PLP transcript is shown). However, Cx29 is expressed earlier in the cerebellum. D, E, Male MD rats have undetectable levels of Cx29 and Cx32 mRNA compared with their age-matched unaffected male littermates. F, Cx29 is expressed before Cx32 mRNA in developing rat sciatic nerves and is barely detectable in adult nerves. G, H, The level of Cx29 mRNA increases in the distal stumps of crushed/regenerating adult rat sciatic nerves, paralleling those of P0 and Cx32, but in transected/permanently denervated distal stumps, Cx29, P0, and Cx32 mRNAs do not increase. NGFR, Nerve growth factor receptor.
To explore the relationship of Cx29 to CNS myelination, we compared its developmental profile with that of PLP, a major component of CNS myelin. In mouse cerebellum and cerebrum (Fig. 2B,C), temporal regulation of Cx29 mRNA expression was similar to that of PLP (Fig. 2B), although in the cerebellum (but not the cerebrum), Cx29 mRNA was detected earlier than PLP mRNA. The precocious appearance of Cx29 did not exclude the possibility that it was expressed only by oligodendrocytes, because other myelin-related mRNAs are expressed before PLP (Scherer et al., 1994
Because neuronal mRNAs are largely excluded from axons, the presence of Cx29 mRNA in sciatic nerve was most consistent with glial expression. We explored this idea by examining Cx29 mRNA expression in developing rat sciatic nerves. Surprisingly, Cx29 mRNA appeared earlier, and declined to lower levels in adulthood, than either Cx32 or P0 mRNAs (Fig. 2F). We also examined Cx29 mRNA expression after treatments affecting myelination in adult sciatic nerve. For this study, we performed whole-nerve transection or crush, which cause degeneration of axons distal to the injury and a dramatic reduction of myelin-related gene expression in the Schwann cells that myelinated those axons previously (Mirsky and Jessen, 1990
Cx29 is not expressed by astrocytes or neurons in the CNS
To determine the cellular source of Cx29 mRNA in the CNS, ISH was performed on sections of adult mouse brain and spinal cord. Cells expressing Cx29 were located in both white and gray matter of spinal cord (Fig. 3A) and brain (data not shown) and typically exhibited small somata. Three different antisense probes produced similar patterns of labeling (data not shown). In addition, a full-length sense probe exhibited a low background (Fig. 3B). PLP/DM20 was also expressed by small cells in both white and gray matter, but PLP/DM20-positive cells were more numerous, especially in white matter (Fig. 3C). We observed no consistent difference in labeling patterns at different spinal levels for either PLP/DM20 or Cx29.
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Figure 3. Cx29 is expressed by small cells in both white and gray matter of spinal cord. In situ hybridization in transverse sections of adult mouse spinal cord. A, An antisense Cx29 RNA probe corresponding to the coding region stains small cells throughout the cord. B, A sense Cx29 probe exhibits relatively low background. C, The pattern of hybridization with PLP/DM20 probe is similar to Cx29, but a larger number of cells are stained, especially in the white matter.
These data suggested that a subset of spinal cord oligodendrocytes expressed Cx29 but left open the possibility that other cell types also expressed Cx29. To investigate this possibility, ISH sections were labeled with antibodies to well characterized neuronal (NeuN) and astrocytic (GFAP) markers, which were visualized using peroxidase-conjugated secondary antibodies. Double staining for Cx29 by ISH (blue) and for the neuronal antigen (brown) is shown in Figure 4A,B. As expected, only cells in the gray matter were labeled for NeuN, which was particularly abundant in neuronal nuclei and to a lesser degree in their cytoplasm (Mullen et al., 1992
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Figure 4. Cx29 is not expressed by neurons or astrocytes in spinal cord. In situ hybridization for Cx29 in transverse sections of spinal cord combined with immunocytochemistry for cell-specific markers is shown. A, B, Cells immunolabeled for NeuN do not correspond to cells labeled by in situ hybridization for Cx29 mRNA (arrows, examples of NeuN-positive cells; arrowheads, Cx29-positive cells). C, Similarly, GFAP-positive cells do not express Cx29 mRNA (arrows, examples of GFAP-positive cells; arrowheads, Cx29-positive cells).
Production and characterization of antibodies against Cx29
Three different specific antibodies against Cx29 were generated. Two were anti-peptide antibodies directed against residues 234-245 or 240-258. Both peptide sequences are located within the cytoplasmic C-terminal domain of Cx29, and neither share significant homology with other connexins or any sequence currently deposited in mouse genomic and EST databases. The third antibody was produced against a GST fusion protein containing residues 220-258, which constituted the majority of the C-terminal domain and overlaps both peptides.
Western blotting was used to characterize the fusion-protein antibody (Fig. 5). Lane 1 of Figure 5 contains a positive control consisting of 10 ng of GST fusion protein where a single immunoreactive band was observed. Although the predicted molecular mass of the fusion protein was 32 kDa, it displayed anomalous migration corresponding to ~36 kDa. The labeling pattern in transiently transfected tissue culture cells was more complex. When transfected with Cx29 alone (data not shown) or with a combination of rat Cx32 (rCx32) and Cx29 (Fig. 5, lane 3), COS cells exhibited three immunoreactive bands. Strong bands were observed at 60 and 29 kDa, whereas a weak band was observed at ~85 kDa. Preabsorption of the antibody with fusion protein eliminated the staining of these bands (data not shown). Cells transfected with rCx32 alone (Fig. 5, lane 2) or empty vector (data not shown) did not display immunoreactive bands.
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Figure 5. Cx29 displays anomalous behavior in Western blots. Affinity-purified anti-Cx29 antibody was produced against a GST fusion protein containing C-terminal residues 220-258. Lane 1, Ten nanograms of purified GST fusion protein. Lane 2, COS cells transfected with rCx32 provide negative control for anti-Cx29 antibody. Lane 3, COS cells cotransfected with rCx32 and Cx29. Bands at ~29, 60, and 85 kDa were detected. Lane 4, Total proteins from adult mouse brain. Strong labeling of several bands in addition to the ones detected in COS cells was observed, possibly resulting from proteolytic digestion (see Discussion). Lane 5, Total proteins from mouse spinal cord present a similar pattern to brain. Lane 6, Total proteins from mouse sciatic nerve. In sciatic nerve, the 60 kDa band was more abundant relative to the 29 kDa band.
Cx32 displays anomalous behavior in SDS-PAGE ascribed to stable association into dimers, trimers, and higher-order aggregates (Hertzberg, 1984
The labeling patterns in mouse tissues containing myelinated nerve resembled, but were not identical to, those of Cx29-transfected cells. Brain (Fig. 5, lane 4) and spinal cord (Fig. 5, lane 5) exhibited immunoreactive bands corresponding to those observed in COS cells plus additional bands. The complex profiles of brain and spinal cord could be explained in part by proteolytic processing of Cx29 and its aggregates. For example, spinal cord displayed a doublet at 29 kDa that we also observed in some preparations of brain (data not shown). In addition, inclusion of protease inhibitors during the sample preparation reduced, although never eliminated, the additional immunoreactive bands (data not shown). In sciatic nerve (Fig. 5, lane 6), the 60 kDa band was much more abundant than the others, which were only observed when high levels of sample were loaded (data not shown). Together, these data suggest that although Cx29 displayed anomalous behavior in SDS-PAGE, the fusion-protein antibody is specific for Cx29.
Cx29 and Cx32 are expressed in different subsets of oligodendrocytes
Double labeling was performed using rabbit anti-Cx29 antibodies together with mouse monoclonal antibodies to Cx32, Caspr, MAG, or Kv1.2. The monoclonal antibody against Cx32 does not stain any cellular element in cx32-null mice (Scherer et al., 1998
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Figure 6. Cx29 and Cx32 are expressed in different subsets of spinal cord oligodendrocytes. Confocal images of horizontal sections of mouse spinal cord double labeled for Cx29 (A, B; red) and Cx32 (A; green) or Caspr (B; green) are shown. Cx29 labels the internodes and juxtaparanodes (A, B; light blue arrowheads) of small diameter fibers and a few somata (A; yellow arrowheads). The Cx32 antibody labels the somata of intrafascicular oligodendrocytes (A; white arrowheads), and labeling extends into fiber tracts. The Caspr antibody (B) strongly labels the paranodal axolemma, thereby illuminating the point that large axons have little Cx29 immunostaining (B; dark blue arrowheads).
The double labeling for Cx29 and Caspr in the CNS also revealed that large myelinated axons typically expressed much less Cx29 than small ones (Fig. 6B). Caspr is an intrinsic membrane protein that is highly concentrated in the paranodal axolemma and thus provides a convenient marker for locating nodes and assessing the fiber diameter. The image in Figure 6B contains many small diameter fibers exhibiting internodal and juxtaparanodal Cx29, whereas the four largest pairs of paranodes (dark blue arrowheads) are not associated with detectable Cx29 staining. In addition, the modest overlap (indicated by yellow) between the Caspr (green) and Cx29 (red) indicated that Cx29 was less concentrated at paranodes than elsewhere along the myelin sheaths of these small myelinated axons.
Cx29 and Cx32 are both expressed in Schwann cells but are differentially localized
We performed similar studies of adult mouse and rat sciatic nerves, taking advantage of the ability to tease nerves into small groups of myelinated fibers. Figure 7 displays two myelinated fibers from a rat, double stained for Cx29 and Cx32. Because the anti-Cx32 antibodies did not work well after aldehyde fixation, this preparation was unfixed, and preservation of structure was not optimal. Nevertheless, Cx32 was enriched in the outer aspects of paranodes and incisures, as reported previously (Bergoffen et al., 1993
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Figure 7. Cx29 and Cx32 are distinctly localized in myelinating Schwann cells. These are images of unfixed teased fibers from rat sciatic nerve, after double labeling for Cx29 (red) and Cx32 (green). Cx32 is strongly expressed in the outermost aspects of paranodes (white arrowheads) and incisures (white arrows). Cx29 is localized primarily to the innermost aspects of paranodes and juxtaparanodes (yellow arrowheads) and more uniformly in incisures (white arrows). Cx29 was enriched in the inner mesaxon (bracketed by blue arrowheads), which spans the internodal region.
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Figure 8. Cx29 is localized to the inner mesaxon. These are images of fixed teased fiber from rat sciatic nerve, after double labeling for Cx29 (red) and either MAG (A; green) or Kv1.2 (B; green). A, The internodal Cx29 signal consists of a pair of lines (bracketed by red arrowheads) that flank a single line of MAG staining (bracketed by green arrowheads); Cx29 and MAG colabel incisures. B, Cx29 and Kv1.2 are strikingly aligned both at the inner mesaxon (bracketed by blue arrowheads) and at the innermost aspect of incisures (arrows). The double nature of the Cx29 and Kv1.2 signals is not apparent at this magnification. Cx29 immunoreactivity is present in the paranode (red region nearest node of Ranvier) and juxtaparanode (yellow area marked by white arrowheads).
Figure 7 also shows Cx29 enrichment in a region corresponding to the inner mesaxon, the site where the first layer of the myelin sheath contacts itself. To explore this internodal Cx29 signal, we used double labeling for Cx29 and MAG (Fig. 8A) or Kv1.2 (Fig. 8B). Fortunately, these antibodies were compatible with aldehyde fixation; therefore, the quality of the preservation in these micrographs was high. MAG was found in the adaxonal Schwann cell membrane and was highly concentrated in the inner mesaxon, incisures, and paranodes (Sternberger et al., 1979
Because Kv1.2 is a neuronal product, its striking colocalization with Cx29 left open the possibility that Cx29 was present in axolemma as well as Schwann cell plasma membrane. Therefore, pre-embedding electron microscopic immunocytochemistry was used to probe the subcellular distribution of Cx29. Antibody binding was detected using a peroxidase-amplification protocol. Labeling was readily observed in the innermost aspects of paranodes and juxtaparanodes and throughout the radial extent of incisures (Fig. 9). Inner mesaxon staining was difficult to obtain in a single plane of section and is not evident in this figure. Together, the immunocytochemistry was most consistent with the expression of Cx29 by Schwann cells, although the possibility of low levels and/or highly localized neuronal expression could not be excluded.
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Figure 9. Immuno-EM of Cx29. These are images of teased fibers that were fixed in 0.5% glutaraldehyde, immunostained for Cx29 using DAB as the substrate for peroxidase, and processed for EM. Two teased fibers are illustrated in A, unstained semithin sections are shown in B and C, and thin sections photographed with an electron microscope are shown in D and E. In all panels, there is DAB throughout incisures (arrowheads) and in the innermost aspects of the juxtaparanodal/paranodal regions (arrows) of myelinating Schwann cells. SC, Schwann cell nucleus; M, myelin sheath; A, axon. Double arrowheads, Node of Ranvier. Scale bars: A-C, 10 µm; D, E, 1 µm.
As myelination progresses and the nodes of Ranvier mature, many myelin-related proteins, including MAG, Caspr, and Kv1.2, undergo striking changes in their subcellular distribution (Baba et al., 1999
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Figure 10. Developmental expression of Cx29. These are images of sections of rat sciatic nerve, double labeled for Cx29 (red; A, C) and MAG (green; B, D). At P3, MAG (B) is mostly diffusely distributed throughout the internodal region, whereas Cx29 (A) is less diffusely localized and more concentrated adjacent to developing nodes. By P10, both MAG and Cx29 display similar distributions (C, D).
Cx29 channel physiology
To determine whether Cx29 could form intercellular channels, we used the paired Xenopus oocyte expression system (Swenson et al., 1989
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Figure 11. Cx29 forms heteromeric channels with Cx32. Connexins were expressed in N2A cells by transient transfection along with fluorescent markers, and dual whole-cell patch recording was performed. A, Normalized conductance-transjunctional voltage (Gj-V) relationship in control pairs expressing only Cx32. Junctional conductance is symmetrical and displays Vj-dependent inactivation (n = 7). The Gj-Vj relationship fitted a double Boltzmann distribution whose fit is superimposed (solid line). B, Gj-V relationship in pairs expressing Cx32 in one cell and both Cx32 and Cx29 in the other (n = 7). The relationship is no longer symmetrical. The Vj indicated on the x-axis is applied to the cell containing both connexins. C-H, Representative examples of recordings from one cell pair with a single heteromeric channel. A transjunction potential of 100 mV was imposed. The Cx32-only cell (top traces) exhibits an ~70 pS channel that rapidly transitions to several substates. The heteromeric channel exhibits similar single-channel conductances, but open states are prolonged without the frequent transitions to substates. The difference in gating behavior is exemplified in I, displaying the average of 30 of such sweeps. The average peak current for both polarities is 7-8 pA, but the time-dependent current decay was well fitted by a single exponential function (solid line) with a larger time constant for the heteromeric than for the homomeric side.
We then tested the ability of Cx29 to form heterotypic (different connexins in each cell) and heteromeric (more than one connexin in the same cell) channels with Cx32. eYFP and eGFP were used to unambiguously mark cells receiving particular combinations of connexins. No coupling was observed in heterotypic pairing of Cx29 and Cx32 (data not shown). However, heteromeric mixing of Cx29 and Cx32 produced channels with properties different from those of Cx32 alone. Junctional currents in control pairs expressing only Cx32 (Fig. 11A) were symmetrical and displayed time-dependent inactivation in response to transjunctional potentials (Vj). Half-maximal inactivation of the conductance occurred at transjunctional voltages between 50 and 60 mV. At 100 mV, the highest transjunctional potential tested, initial conductance dropped to 20% of maximal value. A plot of the normalized conductance versus Vj (Fig. 11A) closely matched a double Boltzmann distribution, in agreement with previous studies (Oh et al., 1999
Junctional currents recorded from one cell pair with a single active intercellular channel are shown in Figure 11C-H. The upper traces in each panel display junctional currents obtained in response to a 100 mV transjunctional potential, where the Cx32-expressing cell was more positive. The bottom trace reflects imposition of a transjunctional potential of the opposite polarity. The Cx32-only cell (upper traces) exhibited activation of a ~70 pS channel that rapidly transitioned to substates, which is reasonably consistent with previous reports using N2A cells (Oh et al., 1999
DISCUSSION
We identified Cx29, a novel connexin that was expressed predominantly if not exclusively in myelinating glial cells in both the CNS and PNS. As summarized in Figure 12, the expression of Cx29 and Cx32 in CNS myelin sheaths appeared to be mutually exclusive: Cx29 was localized to the inner aspects of small myelin sheaths, particularly in the juxtaparanodal region, whereas Cx32 was localized to the outer aspects of large myelin sheaths. Although all myelinating Schwann cells expressed both Cx29 and Cx32, their intracellular distributions differed. Cx29 was concentrated along the inner aspects of paranodes and especially juxtaparanodes, as well as in the inner mesaxon, whereas Cx32 was primarily found in the outer aspects of paranodes. Incisures contained both Cx29 and Cx32. Finally, although Cx29 alone did not form active channels in Xenopus oocytes or N2A cells, it altered the properties of Cx32 channels.
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Figure 12. The organization of connexins in CNS and PNS myelin sheaths. This is a schematic depiction of a myelinated fiber that has both a CNS and PNS myelin sheath. The myelin sheath and axon are depicted as hemisected, and the internodal, paranodal, juxtaparanodal, and nodal regions are shown. In the PNS, Cx29 is depicted as localized to the adaxonal Schwann cell membrane (in the juxtaparanodal region, at the inner mesaxon, and at the innermost aspect of incisures) and between the glial loops in the paranodal region. In the CNS, Cx29 is depicted as localized to the adaxonal oligodendrocyte. Cx32 is localized to the incisures and paranodes of myelinating Schwann cells and the outer membrane of large myelinated fibers in the CNS [modified from Arroyo and Scherer (2000)
The roles of gap junctions in Schwann cells
Myelinating Schwann cells are not joined by gap junctions (Tetzlaff, 1982
Aspects of Cx29 distribution not shared by Cx32 suggest their involvement in functions other than reflexive coupling. In PNS-myelinated axons, the distributions of Cx29 and Kv1.2 near the inner mesaxon were indistinguishable, which was striking and unexpected for two reasons: there is no anatomical evidence for the establishment of gap junctions between axons and their myelin sheaths and, thus, no obvious explanation for the presence of a connexin at the inner mesaxon, and Cx29 and Kv1.2 are expressed in different cells and thus would not be expected to colocalize. Kv1.2, complexed with Kv1.1, Kv
2, and Caspr2 (Poliak et al., 1999
Gap junctions in oligodendrocytes
Like Schwann cells, oligodendrocytes express Cx29 and Cx32 (Dermietzel et al., 1989
Freeze-fracture EM demonstrates that most if not all gap junctions made by oligodendrocytes are with astrocytes (Massa and Mugnaini, 1982
In addition to conventional intercellular junctions, oligodendrocytes may also establish reflexive gap junctions between the wraps of myelin in the paranodes (Sandri et al., 1977
One striking difference in Cx29 distribution between the CNS and PNS was the lack of staining at the inner mesaxon in oligodendrocytes. Immunostaining at the ventral root entry zone (data not shown) suggests that this difference is not an artifact of tissue processing. Within the entry zone, the transition between PNS to CNS myelin occurs at a single node. Inner mesaxon staining for Cx29 is evident in the Schwann cell on one side of the transition node but not in the oligodendrocyte on the other side. A similar phenomenon happens for Kv1.1/Kv1.2: the internodal strands are not found in myelinated CNS axons (Arroyo et al., 2001
Our data add to the long-standing recognition that oligodendrocytes may differ according to the numbers and sizes of the myelin sheaths they form. This idea began with the light microscopic observations of Del Rio-Hortega (1928)
Channel activity of Cx29
The failure of Cx29 to reliably induce intercellular communication when expressed in heterologous systems is difficult to reconcile with some of the in vivo functions we have proposed. However, it cannot be concluded from our studies that Cx29 is incapable of forming active homotypic intercellular channels. Cx29 may appear inactive because neither oocytes nor N2A cells express a necessary cofactor or correctly balance several necessary factors. Regardless, activity in heteromeric intercellular configurations was demonstrated by the alterations in the voltage gating of Cx32 when coexpressed with Cx29. On this basis, it is reasonable to suggest that one in vivo function of Cx29 is to modulate the properties of other connexins or other types of channel proteins. This type of interaction between connexins has proven to be critical for normal development and homeostasis of the ocular lens (White, 2002
FOOTNOTES Received March 27, 2002; revised May 7, 2002; accepted May 10, 2002.
This work was supported by National Institutes of Health (NIH) Grant RO1 GM37751 (D.L.P.), NIH Grant F31 NS41730 (B.M.A.), a National Multiple Sclerosis Society Fellowship (K.A.K.), NIH Grant RO1 NS42878 (S.S.S.), and NIH Grant RO1 GM18974 (D.A. Goodenough). We thank Susan Shumas, Theodore Xu, and Marta Mastroianni for their expert technical assistance.
*B.M.A. and K.A.K. contributed equally to this work.
Correspondence should be addressed to David L. Paul, Department of Neurobiology, Harvard Medical School, 220 Longwood Avenue, Boston, MA 02115. E-mail: dpaul{at}hms.harvard.edu.
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