Article |
Address correspondence to Timothy Vartanian, Harvard Institutes of Medicine, 77 Avenue Louis Pasteur, Boston, MA 02115. Tel.: (617) 667-0864. Fax: (617) 667-0811. E-mail: tvartani{at}caregroup.harvard.edu
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Abstract |
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Key Words: cell-to-cell interaction; multiple sclerosis; axoglial; morphogenesis; genetics
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Introduction |
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Axonally derived signals appear to be required for several aspects of oligodendrocyte and myelin formation (for review see Barres and Raff, 1999). One potential axonally derived signaling molecule critical for oligodendrocyte and myelin formation is neuregulin (NRG)-1 (for review see Carraway and Burden, 1995; Pinkas-Kramarski et al., 1998; Riese and Stern, 1998; Adlkofer and Lai, 2000). In serially passaged OPCs, NRG is mitogenic (Canoll et al., 1996, 1999). Likewise, in conjunction with cAMP and/or PDGF, NRG promotes proliferation of optic nerve OPCs (Shi et al., 1998). In long-term cultures of OPCs ("aged OPCs"), NRG transduces a potent survival signal (Fernandez et al., 2000; Flores et al., 2000) mediated through the Akt pathway (Flores et al., 2000), whereas in vivo inhibitors of NRG significantly reduce the number of optic nerve OPCs (Fernandez et al., 2000). By contrast, in low-density cultures of primary forebrain oligodendrocytes, NRG promotes cell spreading and process extension (Vartanian et al., 1994; Raabe et al., 1997). In spinal cord explants bearing a loss-of-function mutation in the NRG-1 gene, O4+ proligodendroblasts completely fail to develop (Vartanian et al., 1999). This early defect in oligodendrocyte development in NRG-1 mutants can be reversed by the addition of recombinant NRG (Vartanian et al., 1999). Consistent with a role for NRGs during early development of the oligodendrocyte lineage, early ventral structures such as the ventral ventricular zone and floor plate of the spinal cord (Vartanian et al., 1999) and the subventricular zone of the forebrain (Vartanian et al., 1994; Corfas et al., 1995) express NRG at the time that OPCs initially arise.
Multiple factors dictate the cellular effects of NRG. These include the specific ligand, levels and repertoire of receptor expression, and the cellular context. The large number of NRG ligands arise from four known genes with multiple splice and promoter variants (for review see Fischbach and Rosen, 1997; Adlkofer and Lai, 2000). In some cases, splice variants such as the cysteine-rich domain isoform have been shown to be required for specific aspects of nervous system development (Wolpowitz et al., 2000). Receptor usage is relatively restricted for the ligands EGF (to erbB1) and NRG-4 (to erbB4) and relatively broad for NRG-1 (erbB2, erbB3, and erbB4) (for review see Yarden and Sliwkowski, 2001). Signal transduction through erbB receptors occurs as the consequence of essential ligand-induced receptor dimerizations. For example, erbB2 lacks a binding site for NRG, whereas erbB3 lacks intrinsic tyrosine kinase activity, and neither can transduce NRG signals in isolation (Riese and Stern, 1998; Yarden and Sliwkowski, 2001). By contrast, erbB4 is both capable of binding ligand and possesses an intact tyrosine kinase domain (Riese and Stern, 1998; Yarden and Sliwkowski, 2001). Although erbB3 or erbB4 will bind ligand alone, heterodimerization with erbB2 increases the affinity of the receptor complex for its ligand 14-fold (Sliwkowski et al., 1994). ErbB2 appears to be the preferred receptor partner in most, if not all, erbB heterodimers (Graus-Porta et al., 1997), and it increases the complexity of signal transduction after NRG stimulation (Pinkas-Kramarski et al., 1997; Riese and Stern, 1998; Yarden and Sliwkowski, 2001). Furthermore, unique and overlapping docking sites for adapter proteins and cytosolic enzymes exist for individual erbBs, making them capable of transducing both common and distinct signals (Plowman et al., 1993; Wang et al., 1998a; Jones et al., 1999). The cellular context of NRGreceptor interactions is also critical for determining cellular responses. For example, neural crest cells, Schwann cell precursors, and Schwann cells all express erbB2 and erbB3 receptors for NRG. In multipotent crest cells, NRG-1 specifies a glial fate (Shah et al., 1994) and in Schwann cell precursors, NRG-1 specifies survival (Dong et al., 1995), while in Schwann cells NRG-1 specifies proliferation (Dong et al., 1995; Morrissey et al., 1995).
Here we examine the requirement for erbB2 signaling during development of the spinal cord oligodendrocyte lineage. Through a targeted disruption of the murine erbB2 gene, we demonstrate that, in striking contrast to the absence of NRG-1, the absence of erbB2 has no effect on the formation of the early oligodendrocyte lineage. However, ErbB2 does appear to be essential for normal development of later stages of the oligodendrocyte lineage. In the absence of erbB2, the development of differentiated O1+ oligodendrocytes was dramatically deficient. In addition, the limited O1+ oligodendrocytes that develop in the absence of erbB2 signaling failed to ensheath neurites and form myelin in long-term cultures. These findings are analogous to those in the peripheral nervous system (PNS), in which an erbB2/Schwann cell conditional mutant (Krox20-cre/+; erbB2flox/-) shows reduced numbers of Schwann cell precursors and deficient PNS myelination (Garratt et al., 2000). The inhibition of oligodendrocyte differentiation in the absence of erbB2 appears lineage-specific, since the lack of erbB2 did not quantitatively effect astrocyte development or the extent of neurite outgrowth. Our data suggest that distinct receptor combinations are used by cells of the oligodendrocyte lineage to transduce NRG signals at distinct stages in development. Interestingly, Canoll et al. (1996)(1999) observed an increase in erbB2 expression as oligodendrocytes differentiate from OPCs. Although erbB2 signaling is not required during early OPC development, our findings suggest it is essential for later oligodendrocyte differentiation and the effective genesis of the myelin internode.
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Results |
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A predominant role for ErbB2 in oligodendrocyte development: neurite outgrowth and astrocyte development appear normal in the absence of erbB2
Other neural cell types express erbB receptors (Pinkas-Kramarski et al., 1994; Corfas et al., 1995). To test whether erbB2 was required for the differentiation of all neural cell types, spinal cord explants from E9.5 wild-type, erbB2+/-, and erbB2-/- embryos were assayed for neurite outgrowth and astrocyte development after 10 d in vitro. Explants were fixed and stained with antibodies to neurofilament (NF) to detect neurites, or to glial fibrilary acidic protein (GFAP) to detect astrocytes. Neurite outgrowth was extensive and comparable in explants from wild-type, erbB2+/-, and erbB2-/- embryos (Fig. 4)
. Astrocytes express the NRG receptors erbB2, erbB3, and erbB4 (Pinkas-Kramarski et al., 1994; Vartanian et al., 1997); however, in contrast to the effects on the oligodendrocyte lineage, the number and morphology of GFAP+ astrocytes appeared similar between wild-type, erbB2+/--, and erbB2-/--derived explants (Fig. 4). These data indicate that erbB2 signaling is not essential for astrocyte development, although the presence of astrocyte mitogens in culture serum supplements may compensate for the absence of erbB2 signaling. These data suggest that development of the oligodendrocyte lineage is most dependent on erbB2 signaling.
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Discussion |
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NRG-mediated signals transduced through diverse erbB receptors are required for distinct stages in oligodendrocyte development
Although the precise function of NRGs during the early development of OPCs is unclear, during later stages of oligodendrocyte development there is a clear role for NRG mediated signals. NRGs appear to be required for the survival of established OPCs (Fernandez et al., 2000; Flores et al., 2000). In spinal cord explants grown in the presence of a soluble inhibitor of NRG, O4+ proligodendroblasts do not develop (Vartanian et al., 1999). Similarly, O4+ proligodendroblasts do not develop in spinal cord explants from NRG-1deficient mice, and this can be reversed by the addition of recombinant NRG-1 (Vartanian et al., 1999). It was thus surprising that in the erbB2 null mouse there is normal development of O4+ proligodendroblasts in explants derived from erbB2 null embryos. These findings suggest that in oligodendrocyte lineage cells expressing erbB2, erbB3, and erbB4, signals derived from the erbB2 cytosolic domain are not essential for the generation of the lineage before the appearance of O4+ proligodendroblasts. Similarly, the normal development of O4+ proligodendroblasts in erbB2-/- explants suggests that NRG receptors other than erbB2 are capable of transducing the signals necessary for the formation of these cells. Signals transduced by erbB2 do appear to be essential for the appearance of differentiated O1+ oligodendrocytes, however, since these cells fail to develop in erbB2-/- explants despite the presence of high concentrations of insulin, PDGF-AA, or LIF. These observations strongly suggest that erbB2 transduces a distinct signal required for the appearance of terminal-differentiated oligodendrocytes and myelination.
The ability of individual erbB receptors to transduce distinct intracellular signals is well established in transformed cell lines (for review see Pinkas-Kramarski et al., 1998; Riese and Stern, 1998; Yarden and Sliwkowski, 2001). For example, the cellular response, patterns of receptor phosphorylation, and recruitment of intracellular signaling proteins varies between erbB4 homodimers stimulated with different NRGs (Sweeney et al., 2000). Secondly, receptor usage is critically important to signal diversification (Pinkas-Kramarski et al., 1996). There is evidence that individual class I receptors transduce overlapping and nonoverlapping intracellular signals. For example, analyses of the potential SH2 docking sites on erbB receptors demonstrated both unique as well as homologous sites, indicating the potential for overlapping and nonoverlapping signaling through individual receptors (Carraway and Cantley, 1994). Furthermore, in addition to transducing signals common to other erbB receptors, erbB4 appears to activate distinct signaling pathways (Jones et al., 1999; Zhao et al., 1999; Huang et al., 2000). In conjunction with our previous results, the current data from the erbB2-/- mouse shows that in primary cells, the NRG receptor erbB2 is likely transducing distinct intracellular signals necessary for the appearance of differentiated oligodendrocytes.
Several lines of evidence suggest that the signaling through the erbB2 receptor mediates a differentiation rather than survival signal for emerging oligodendrocytes. For example, there is no apparent increase in cell death in the oligodendrocyte lineage in the absence of erbB2 signaling and addition of known growth/survival factors fails to reverse this cellular phenotype. It remains possible that interactions between different classes of receptors are required for the differentiation of oligodendrocytes. The inability of LIF to enhance survival of erbB2-/- oligodendrocytes may reflect interactions between erbB2 and the LIF receptor gp130. In prostate cancer cells overexpressing erbB2, IL-6 induces a ligand-dependent association of erbB2 with the gp130 component of the IL-6 receptor and is required for mitogen-activated protein kinase activation by IL-6 (Qiu et al., 1998). The current work does not exclude such a possibility. Furthermore, although it seems likely that the lack of differentiated oligodendrocytes in erbB2-/--derived explants reflects cell-intrinsic signaling in OPCs, astrocytes and neurons express NRG receptors and the effects on oligodendrocyte development may result from an erbB2-regulated synthesis of an inhibitor of oligodendrocyte differentiation in these other cell types.
Axonally derived signals are necessary for oligodendrocyte development and myelination
By the time OPCs populate white matter tracts axonogenesis is completed, and thus oligodendrocyte differentiation and myelination follow axonogenesis. This timing is consistent with the inhibitory influence of CNS myelin on axonal growth (Filbin et al., 1990; Bandtlow and Schwab, 2000; Chen et al., 2000; GrandPre et al., 2000). The critical importance of axonal-derived signaling at multiple stages of oligodendrocyte development is inferred from several experimental studies. During development, oligodendrocyte numbers are closely matched to the number of axons. Increasing axon numbers increases the number of OPCs in parallel (Burne et al., 1996). Removal of axons by neonatal enucleation or optic nerve transection (Fulcrand and Privat, 1977; Privat et al., 1981; David et al., 1984; Valat et al., 1988; Ueda et al., 1999) significantly reduces the number of optic nerve oligodendrocytes; although, some develop normally in the absence of axons (Ueda et al., 1999) as they do in the absence of erbB2. Thus, in neonatal mammals, axonal signals appear to induce proliferation of OPCs and survival of oligodendrocytes (Fulcrand and Privat, 1977; Privat et al., 1981; David et al., 1984; Valat et al., 1988; Barres et al., 1992a; Barres and Raff, 1993). In the postnatal and adult mammalian CNS, however, axonal signals appear to serve a different purpose. Specific signals from the axon are required for myelination since other elements such as dendrites do not undergo myelination (Lubetzki et al., 1993). In the adult, axotomy or neurectomy results in axonal degeneration and concomitant myelin degradation in the absence of significant oligodendrocyte apoptosis (Fulcrand and Privat, 1977; Stoll et al., 1989; Wisniewski, 1983; Butt and Kirvell, 1996). The physical presence of axons is sufficient to maintain myelin internodes. In the C57BL/Ola mouse, a spontaneously occurring mutant with abnormally prolonged Wallerian degeneration (Brown et al., 1991; Ludwin and Bisby, 1992), distal axonal segments, and oligodendrocyte-myelin units remain intact for up to 4 wk after axotomy or transection compared with 12 d for normal controls (Ludwin and Bisby, 1992). The ability of a distal, posttransection axonal segment to provide trophic influences is not limited to oligodendrocytes and Schwann cells. The neuromuscular junction, which also requires axonal-derived NRG for its development (Fischbach and Rosen, 1997; Sandrock et al., 1997; Fromm and Burden, 1998; Wolpowitz et al., 2000), is also maintained for prolonged periods of time after transection in the C57BL/Ola mouse (Ribchester et al., 1995).
At least two candidate molecules have been described that might mediate the axonally derived signals which influence oligodendrocyte development: Jagged1 and NRG. Jagged1 acting through Notch receptors on OPCs is a potent inhibitor of oligodendrocyte differentiation in the optic nerve (Wang et al., 1998b). Jagged1 is expressed on axons and its levels fall as myelination proceeds, suggesting it may be an important signal inhibiting differentiation or myelination until the appropriate developmental stage. Therefore, it is possible that the defect in terminal differentiation of oligodendrocytes in the absence of erbB2 could be the consequence of up-regulation of Jagged1 or related ligands in spinal cord neurons.
NRG is a candidate axonal signal for oligodendrocyte formation and myelination
In the developing nervous system, NRG is localized to neurons and axons (Corfas et al., 1995; Dong et al., 1995; Jo et al., 1995; Sandrock et al., 1995; Trachtenberg and Thompson, 1996; Loeb et al., 1998) as well as floor plate structures in early CNS development (Corfas et al., 1995; Vartanian et al., 1994, 1999). In vitro studies demonstrate that axonally derived NRG in its membrane-associated form is capable of activating erbB receptors (Vartanian et al., 1997), indicating that axonally associated NRG can mediate its effects as a consequence of direct axonalglial interactions.
In the PNS, NRG plays multiple distinct roles in Schwann cell development. Early in development, NRG induces a glial fate in neural crest precursors (Shah et al., 1994). In committed Schwann cell precursors axonally derived NRG serves as a survival factor (Dong et al., 1995). In mature Schwann cells axonally derived NRG is responsible for all or most of the survival and mitogenic effects of axons on the Schwann cell lineage. For example, antibodies to erbB2 inhibit axon-induced proliferation of Schwann cells (Morrissey et al., 1995). Similarly, addition of exogenous NRG markedly reduced Schwann cell apoptosis during normal development or as the consequence of axotomy (Grinspan et al., 1996; Trachtenberg and Thompson, 1996). Furthermore, in mice bearing mutations in NRG-1 or the NRG receptors erbB2 and erbB3, there is a profound reduction in the number of Schwann cells (Lee et al., 1995; Meyer and Birchmeier, 1995; Erickson et al., 1997; Riethmacher et al., 1997; Morris et al., 1999), as well as effects on axonal fasciculation and target finding (Morris et al., 1999; Wolpowitz et al., 2000). A conditional erbB2 mutation in promyelinating and myelinating Schwann cells results in diminished PNS myelination (Garratt et al., 2000).
Likewise, our data suggest that in the CNS, NRG plays multiple distinct roles in oligodendrocyte development which are mediated by distinct erbB receptors. NRG, possibly derived from ventral midline structures, but not the erbB2 receptor, is required for oligodendrocyte precursors to develop to O4+ cells (Vartanian et al., 1999). NRG, possibly derived from axons, and the erbB2 receptor are required for differentiation of O4+ precursors to oligodendrocytes and subsequent steps in myelination. Although the requirement of erbB2 in oligodendrocyte development and ensheathment of axons may be cell autonomous, it remains possible that mutations of erbB2 influence oligodendrocyte development indirectly through effects on neurons or astrocytes.
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Materials and methods |
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ErbB2 null mice and spinal cord explants
To generate erbB2+/+, erbB2+/-, and erbB2-/- embryos, litters were obtained from timed pregnancies of erbB2+/- female and erbB2+/- male matings 9.5 dpc. Each embryo was given a code number and spinal cords were dissected out and cut transversely into 12-mm fragments for explant culture onto polylysine and laminin-coated coverslips in DME, N2 additives, and 2% FBS. The remainder of each embryo was used to isolate genomic DNA for Southern blot analysis. To study myelination in vitro, medium containing N2 additives, 0.5 ng/ml PDGF-AA, and 2% FBS was used. These are conditions that we have previously determined to be optimal for myelination in spinal cord cultures.
To generate purified populations of OPCs and oligodendrocytes, cells were immunopanned from newborn rat spinal cord using mAbs A2B5, O4, or O1, respectively, as described previously (Robinson et al., 1998). Purity of the cell population was assayed on a separate cell aliquot 12 h after panning, and in all cases was >98% pure panned cells. Samples were snap frozen in liquid nitrogen and stored at -70°C until use.
Low-density cultures of enriched oligodendrocytes were generated as follows. Spinal cord explants from E9.5 mice were cultured in poly-L-ornithinecoated 24-well plates with a single explant per well. After 8 d in vitro, the medium was changed to DME with N2 additives and 20% FBS and the plates were rotated for 16 h at 200 rpm at 37°C. Supernatants from individual explants were plated into individual wells of 8-well Permanox chamber slides (Nunc). After 2 h, the majority of cells adhered and the medium was replaced with DME containing N2 additives, 0.5 ng/ml PDGF-AA, and 1% FBS. OPCs were briefly expanded with PDGF (10 ng/ml) and bFGF (10 ng/ml) for 4 d, then switched to medium containing N2 additives, 0.5 ng/ml PDGF, and 1% FBS for an additional 36 h, then immunostained for surface galctocerebroside with the mAb O1. After fixation the cell density was determined by cell counts and averaged 120 cells/cm2. Approximately 60% of the cells were morphologically within the oligodendrocyte lineage. The remaining cells were morphologically astrocytes and fibroblasts. No neurons were observed.
Immunofluorescence microscopy
For A2B5, O4, or O1 immunofluorescence, live explant cultures were incubated for 15 min with the relevant mAb, washed with PBS, then fixed in fresh 4% paraformaldehyde in PBS for 7 min at ambient temperature, washed with PBS, then incubated with the relevant secondary antibody (Jackson ImmunoResearch Laboratories) and visualized by epifluorescence. For NF and GFAP immunofluorescence, cells were treated with 0.125% Triton X-100 in PBS for 20 min before incubation with primary antibody. For MBP staining, after fixation with paraformaldehyde, cells were permeabilized with ice-cold methanol for 10 min before incubation with primary antibody. Primary antibodies used were against the following: A2B5, O4, and O1 (American Type Culture Collection), MBP SMI99 (Sternberger Monoclonals, Inc.), NF 200 kD (Roche and Sigma-Aldrich), GFAP (Roche), erbB2 and erbB3 (Upstate Biotechnology), erbB4 (Santa Cruz Biotechnology, Inc.). Immunofluorescent images were obtained using a Nikon Eclipse 660 microscope with 20, 40, and 60x objectives, exposing 400 ASA Kodak color 35-mm film, images were then digitized using a slide scanner.
Cell counts
In wild-type and erbB2+/- explants (after unblinding), O4+ and O1+ oligodendrocytes were dense within the explant itself and thus difficult to count with any certainty. Thus, for wild-type and erbB2+/- explants, the outgrowth was counted. In erbB2-/- explants, there are so few O1+ oligodendrocytes that the occasional O1+ cell within the explant is easily identified and can be counted. Thus, we included O1+ cells within the explant for the erbB2-/- explants, but excluded them in the erbB2+/+ and erbB2+/- explants. Thus, the results were biased against the observed difference. There were so few O1+ oligodendrocytes within the erbB2-/- explants (12 of 2030) that the results did not statistically differ whether or not they were included in the analysis.
Viability studies
To assess cell death of oligodendrocytes (O1+ and O4+) in the presence or absence of erbB2, spinal cord explant cultures were immunolabeled with O4 or O1 mAbs, fixed with 95% ethanol/5% glacial acetic acid for 1 min, incubated with FITC goat antimouse IgM (µ chain specific), and stained with propidium iodide (20 mg/ml) for 5 min. The total number of O4+ or O1+ oligodendrocytes and the number of O4+ or O1+ oligodendrocytes showing pyknotic nuclei were counted by epifluorescence microscopy. Camptothecin was used at the concentration of 10 µM overnight to induce cell death. Camptothecin is a cytotoxic plant alkaloid that induces DNA damage by inhibiting the activity of DNA topoisomerase-I (Morris and Geller, 1996).
RT-PCR of messages encoding erbB receptors
Total RNA was isolated from rat OPCs (A2B5) and oligodendrocytes (O4+) by using Trizol Reagent (Life Technologies). Complementary DNA (cDNA) was synthesized from total RNA with oligo(dT) primers and SuperScript II reverse transcriptase (Life Technologies) according to the manufacturer's protocol. A specific cDNA fragment was amplified by Platinum TagPCRx DNA polymerase (Life Technologies) using specific primers for erbB2, erbB3, or erbB4 (36 cycles of 94°C for 2 min, 58°C for 1 min and 72°C for 2 min, and a final 10 min 72°C extension). Amplified sequences by PCR were the regions corresponding to nucleotides 17262133 (408 bp) of the rat erbB2 mRNA sequences (EMBL/GenBank/DDBJ accession no. NM_017003), nucleotides 36064002 (397 bp) of the rat erbB3 mRNA sequences (EMBL/GenBank/DDBJ accession no. NM_017218), and nucleotides 18912058 of the rat erbB4 mRNA sequences (EMBL/GenBank/DDBJ accession no. AF041838). Primers for PCR were: erbB2 sense 5'-CGAGTGTCAGCCTCAAAACA-3', antisense 5'-GTCAGCGGCTCCACTAACTC-3'; erbB3 sense 5'-CGTCATGCCAGATACACACC-3', antisense 5'-CTCCTCGTACCCTTGCTCAG-3'; and erbB4 sense 5'-AACTGCACCCAGGGGTGTAA-3', antisense 5'-GACATAAACGGCAAATGTCA-3'.
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Footnotes |
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Acknowledgments |
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This work was supported by grants from the National Institute of Neurologic Disorders and Stroke (NS02028 to T.K. Vartanian and NS30800 to R.H. Miller), P01 NS38475-01 and the United States National Multiple Sclerosis Society (FA1311-A-1 to S.K. Park and RG2912-A-1 to T.K. Vartanian).
Submitted: 6 August 2001
Accepted: 10 August 2001
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