Abstract
One of the more complex developmental processes occurring postnatally in the CNS is the formation of the myelin sheath by oligodendrocytes. To examine the molecular events that take place during myelination, we isolated oligodendrocyte-derived cDNA clones, one of which (p421.HB) represents a putative alternatively spliced isoform of rat brain-specific phosphodiesterase I (PD-Iα) and a species homolog of the human cytokine autotaxin. Analysis of the structural composition of the p421.HB/PD-Iα protein suggests a transmembrane-bound ectoenzyme, which, in addition to the phosphodiesterase-active site contains presumed cell recognition and Ca2+-binding domains. Consequently, it may be involved in extracellular signaling events. Expression of p421.HB/PD-Iα is enriched in brain and spinal cord, where its mRNA can be detected in oligodendrocytes and in cells of the choroid plexus. Expression in the brain increases during development with an intermediate peak of expression around the time of active myelination and maximal expression in the adult. We have identified four presumably alternatively spliced isoforms, two of which appear to be CNS-specific. Decreased levels of p421.HB/PD-Iα mRNA in the dysmyelinating mouse mutant jimpy, but notshiverer, suggest a role for p421.HB/PD-Iα during active myelination and/or late stages of oligodendrocyte differentiation. Furthermore, p421.HB/PD-Iα mRNA levels were reduced in the CNS at onset of clinical symptoms in experimental autoimmune encephalomyelitis. These data together implicate the importance of p421.HB/PD-Iα in oligodendrocyte function, possibly through cell–cell and/or cell–extracellular matrix recognition.
Proper function of the mammalian nervous system not only requires the delicate control of neuronal migration and differentiation during embryonic development but also the precise regulation of one of the most complex postnatal developmental steps, myelination. Understanding myelination is additionally important, because the pathogenesis of human demyelinating diseases, such as multiple sclerosis, is still unclear. A number of animal models, such as rodent dysmyelinating mutants (for review, see Nave, 1994) and experimental autoimmune encephalomyelitis (EAE) (Martini and McFarland, 1995; Tsunoda and Fujinami, 1996), provide valuable tools to address different aspects of myelination and remyelination. However, detailed insight into the cellular biology of the oligodendrocyte, the myelin-forming cell of the CNS, is needed to obtain a comprehensive picture of the complex mechanisms that lead to normal myelin sheath formation or to insufficient myelination and myelin breakdown under pathological conditions. Within the past decade oligodendrocyte-specific proteins and their genes have been studied extensively (for review, see Campagnoni and Macklin, 1988; Lemke 1988;Mikoshiba et al., 1991; Ikenaka and Kagawa, 1995), but despite these investigations, the precise mechanism of myelination is still poorly understood.
In studies designed to identify novel genes that could potentially be important during oligodendrocyte differentiation and myelin sheath formation, several cDNA clones were obtained by differential cloning techniques (Baba et al., 1994). One of these cDNA clones, p421.HB, represents a putative alternatively spliced isoform of rat brain-specific phosphodiesterase I/nucleotide pyrophosphatase (Narita et al., 1994). Phosphodiesterase I (oligonucleate 5′-nucleotidohydrolase; EC3.1.4.1.) is a membrane-bound glycoprotein that catalyzes the hydrolysis of various nucleotide polyphosphates. Sequence analysis for rat brain-specific phosphodiesterase I revealed, in addition to the phosphodiesterase homologous region, two somatomedin B domains and an EF hand-like motif. Recently, autotaxin was isolated as a new cytokine from human tumor cell lines (Murata et al., 1994; Lee et al., 1996), and it was shown to represent the human homolog of rat brain-specific phosphodiesterase I (Kawagoe et al., 1995; Lee at al., 1996). A soluble form of autotaxin, generated through proteolytic cleavage, was shown to be involved in a G-protein-coupled stimulation of chemotactic and chemokinetic responses of tumor cells. The functional importance of phosphodiesterase I/autotaxin in the CNS has been unclear.
To gain knowledge about possible functional roles of phosphodiesterase I in the CNS, we analyzed the expression of phosphodiesterase I isoforms during development and in different cell types of the normal rat CNS. We have focused our subsequent studies on phosphodiesterase I expression in oligodendrocytes, because the CNS-specific form of the protein appears to be enriched in oligodendrocytes. Thus, we have characterized phosphodiesterase I mRNA levels in the CNS of dysmyelinating mouse mutants and in the presence of inflammatory lesions in EAE. The data presented here propose a functional role for phosphodiesterase I during myelination in the CNS.
MATERIALS AND METHODS
Animals. For in situ hybridization 4-d-old, 21-d-old, and adult (older than 60 d) Sprague Dawley rats were analyzed (Harlan Sprague Dawley, Indianapolis, IN). For analysis of dysmyelinating mouse mutants, 21-d-old shiverer,jimpy, and trembler mice were used. All mutant and age-matched control mice were bred at the departmental animal facilities. Female (SWR × SJL)F1(H-2q,s) mice used for induction of EAE were bred at the Research Institute of the Cleveland Clinic Foundation by mating SWR/J (H-2q) females with SJL/J (H-2s) males purchased from The Jackson Laboratory (Bar Harbor, ME).
Isolation and sequence analysis of cDNA clones. The cDNA clone p421.HB represents one of the clones isolated by differential and subtractive screening of an oligodendrocyte-derived cDNA library (Baba et al., 1994). Briefly, oligodendrocyte cultures were prepared by the method of McCarthy and DeVellis (1980), and poly(A)+RNA isolated from these cultures was used for construction of a cDNA library into the vector λZAPII (Stratagene, La Jolla, CA). Differential (rat brain vs liver) and subtractive screening (rat brain minus spleen) of this cDNA library yielded 10 cDNA clones that were shown to be brain-enriched by Northern blot analysis.
Sequence analysis and nucleotide and amino acid homology searches were performed using the BLAST algorithm (Altschul et al., 1990) as provided by the National Center for Biotechnology Information (Bethesda, MD), and for protein sequence pattern searches the Search Launcher provided by the Baylor College of Medicine (Houston, TX) was used.
Northern blot analysis. RNA was isolated by the single-step RNA isolation method developed by Chomczynski and Sacchi (1987). Ten micrograms of total RNA were separated on 1% agarose gels containing 2.2 m formaldehyde. RNA was transferred to MagnaGraph nylon membranes (Micron Separations Inc., Westboro, MA) and hybridized at 42°C with the complete cDNAs of p421.HB and cyclophilin (Danielson et al., 1988), labeled with [32P]dCTP using the High Prime labeling kit according to the manufacturer’s instructions (Boehringer Mannheim, Indianapolis, IN). Blots were analyzed using autoradiography and phosphorimaging techniques in combination with the software programs Image Quant (Molecular Dynamics, Sunnyvale, CA) and Excel (Microsoft).
In situ hybridization. For in situ hybridization, digoxigenin-labeled cRNA probes (sense and antisense) were prepared using T3-, T7-, or Sp6-RNA polymerase according to the manufacturer’s instructions (Boehringer Mannheim) (also see Krieg and Melton, 1984) and hydrolyzed under alkaline conditions to obtain fragments of ∼250 bp in length. The p421.HB/phosphodiesterase Iα (PD-Iα)-specific probe contained the complete p421.HB insert of 1.6 kb; the probe specific for proteolipid protein (PLP) covered the entire coding region (Sorg et al., 1987). Fixation and hybridization of fresh frozen cryostat sections was performed in a modified version of methods described elsewhere (Bartsch et al., 1992, Fuss et al., 1993,Panoskaltsis-Mortari and Bucy, 1995). Briefly, cryostat sections (10–12 μm) were thaw-mounted onto Superfrost/plus slides (Fisher Scientific, Pittsburgh, PA) and fixed in 3% paraformaldehyde in PBS, pH 7.3. After treatment with 0.1 m HCl and subsequent acetylation, sections were prehybridized at 37°C in the presence of 50% formamide. Hybridizations were performed in the presence of 50% formamide at 55°C. After RNase treatment [40 μg/ml STE (500 mm NaCl, 20 mm Tris-HCl, pH 7.5, and 1 mm EDTA], sections were washed in 0.2× SSC containing 50% formamide at 55°C, and bound cRNA was detected using an alkaline phosphatase-coupled antibody to digoxigenin with subsequent color development in the presence of 4-nitroblue tetrazolium chloride/5-bromo-4-chloro-3-indolylphosphate and levamisol.
Cell cultures. Mixed glial cell cultures and oligodendrocyte cultures used for reverse transcription-PCR (RT-PCR) analysis were prepared from the cerebrum of 1- to 3-d-old rats using the method described by McCarthy and DeVellis (1980). Astrocyte cultures were obtained from mixed glial cultures after oligodendrocytes were shaken off.
Oligodendrocyte cultures used for combined in situhybridization and immunocytochemistry were prepared from the cerebrum of postnatal rats (1–3 d old) by immunopanning (Barres et al., 1992) using the A2B5 antibody (kindly provided by A. Nishiyama, Cleveland Clinic Foundation) (Eisenbarth et al., 1979). Briefly, after removal of the meninges, tissue was minced in HBSS (Life Technologies, Grand Island, NY) and incubated for 30 min at 37°C in 0.06% (w/v) trypsin and 0.06% (w/v) pancreatin. Cells were collected by centrifugation and resuspended in DMEM (Life Technologies) containing 10% fetal calf serum (FCS). The cell suspension was transferred to petri dishes coated with the A2B5 antibody (suspension from three brains per dish, 100 mm diameter) and incubated for 30 min at 37°C. Nonadherent cells were washed off, and adherent cells, enriched for A2B5-positive oligodendrocyte progenitor cells, were plated onto poly-l-lysine (Sigma, St. Louis, MO)-coated coverslips after removal from the A2B5-coated dish. Cells were cultured overnight in DMEM/10% FCS; medium was exchanged to DMEM containing 1× N2 supplement (Life Technologies) and platelet-derived growth factor (R & D Systems, Minneapolis, MN) at a concentration of 10 ng/ml for stimulation of progenitor cell proliferation. After 2 d cells were cultured in DMEM containing 1× N2 supplement and 3,3′-5-triiodo-l-thyronine (10 ng/ml; Sigma) to allow oligodendrocyte progenitor cells to differentiate. Cells were analyzed for p421.HB/PD-Iα mRNA expression after 8 d in culture.
Combined in situ hybridization and immunocytochemistry. Oligodendrocyte cultures were fixed in 3% paraformaldehyde in PBS for 1 hr. In situ hybridization was performed as described for the brain sections above, except that fixed cells were hybridized at 37°C, and the RNase treatment after hybridization was omitted. For detection of the digoxigenin-labeled cRNA probes anti-digoxigenin Fab fragments from sheep (Boehringer Mannheim) in combination with a biotin-coupled anti-sheep IgG antibody (Jackson ImmunoResearch, West Grove, PA) and fluorescein avidin D (Vector Laboratories, Burlingame, CA) was used. Subsequently, cells were incubated with a polyclonal anti-2′,3′-cyclic nucleotide 3′-phosphodiesterase (CNP) antibody (kindly provided by T. Kurihara, Soka University, Tokyo, Japan) (Kurihara et al., 1992), followed by an incubation with a Texas Red-coupled anti-rabbit IgG antibody (Jackson ImmunoResearch). Fluorescent signals were analyzed by a confocal laser scanning microscope (Aristoplan; Leica, Deerfield, IL). Confocal images represent optical sections of ∼1 μm and an average of 15 line scans.
RT-PCR. Ten micrograms of total RNA of each tissue were used for reverse transcription using Superscript II (Life Technologies) as described by Frohman (1994) in the classic protocol for rapid amplification of cDNA ends. For amplification, 2.5–10% of the reverse transcription reaction was used with the following sets of primers: primer 1 (sense), located at nucleotides (nt) 1746–1773 of rat phosphodiesterase I (Narita et al., 1994); primer 3 (antisense), nt 2056–2031, which are flanking the proposed alternatively spliced 75 bp sequence (nt 1862–1937); and primer 2 (sense) at nt 1868–1895, which is located within the proposed alternatively spliced sequence. The amplification reaction was performed in a final volume of 50 μl in 1× PCR buffer (16.6 mm[NH4]2SO4, 67 mm Tris, pH 8.8, and 6.7 mm MgCl2), 10% DMSO, 1.5 mm each dNTP, 25 pmol each of the primer oligonucleotides, and 1.25 U of Taq polymerase. After 30 cycles (1 min, 94°C; 1 min, 55°C; and 2 min 68°C) one-third of the reaction was analyzed on a 3.5% NuSieve GTG agarose gel (FMC Bioproducts, Rockland, ME). Ratios of amplification products obtained in each of the reactions were calculated by intensity determinations using scanned images of ethidium bromide-stained gels of at least three experiments and the image analysis software NIH-Image (National Institutes of Health).
Induction of EAE. For EAE induction, (SWR × SJL)F1 mice were immunized with the encephalitogenic peptide p139–151 (HSLGKWLGHPDKF) of proteolipid protein (Tuohy et al., 1989) as described previously (Yu et al., 1996). Each mouse was injected on day 0 subcutaneously with 100 nmol of peptide plus 400 μg of Mycobacterium tuberculosis H37RA (Difco, Detroit, MI) in 200 μl of H2O/incomplete Freund’s adjuvant (Difco) emulsion and on days 0 and 3 intraveniously with 0.6 × 1010 Bordetella pertussis bacilli (Michigan Department of Public Health, Lansing, MI). Mice were weighed and examined daily, and animals were killed for further analysis at onset of clinical signs: clinical grades 1 (decreased tail tone or slightly clumsy gait) and 2 (tail atony, moderately clumsy gait, and/or poor righting ability). Control animals, which were injected with BSA, were taken at each time point for each affected animal.
RNase protection assay. RNase protection assay (RPA) was performed essentially as described by Saccomanno et al. (1992). Briefly, cRNA fragments were synthesized in the presence of 50 μCi of [32P]UTP and 100 μm (for p421.HB), 200 μm (for PLP), or 300 μm (for cyclophilin) UTP from 0.5 μg (for p421.HB and PLP) or 0.25 μg (for cyclophilin) of linearized template DNA using T7 RNA polymerase according to the manufacturer’s instructions (Promega, Madison, WI). The p421.HB template was obtained by RT-PCR on cellular RNA isolated from mouse brains. The p421.HB/PD-Iα cRNA probe represented 147 nt of the mouse coding region (nt 2069–2216 in the rat PD-Iα sequence;Narita et al., 1994); the probe for PLP represented 228 nt of the 3′-untranslated sequences (nt 1242–1470 of PLP; Sorg et al., 1987); and the probe for cyclophilin covered 290 nt of the coding region (nt 48–338; Danielson et al., 1988). Ten micrograms of total RNA were hybridized in 80% formamide, 40 mm PIPES, pH 6.5, 400 mm NaCl, and 1 mm EDTA at 45°C with 1 × 106 and 5 × 105 cpm of the labeled cyclophilin and p421.HB or PLP cRNA, respectively. “Non-hybridized” RNA was digested with ribonuclease T2 (Life Technologies) at concentrations of 20–50 U/ml for 1 hr at 37°C. Protected RNA duplexes were separated on a 6% polyacrylamide/urea gel. Further analysis of three independent experiments using RNA of at least two animals each was performed using autoradiography and phosphorimaging techniques in combination with the software programs Image Quant (Molecular Dynamics) and Excel (Microsoft).
RESULTS
p421.HB/PD-Iα represents a member of the somatomedin/phosphodiesterase family of proteins
To get new insight into the molecular basis of oligodendrocyte function, an oligodendrocyte-derived cDNA clone, designated p421.HB, was further characterized. p421.HB represents a partial cDNA clone with sequence identity to the 3′-end of rat brain-specific PD-Iα (Narita et al., 1994). The common sequences between p421.HB and PD-Iα encompass the region coding for amino acids 391–885 of PD-Iα through the first 125 nucleotides of the 3′-untranslated region. The 75 bp region coding for amino acids 596–615 of PD-Iα is absent in the p421.HB cDNA (Fig. 1, 25 aa). Further homology analysis by us and others (Murata et al., 1994; Narita et al., 1994; Kawagoe et al., 1995; Lee et al., 1996) revealed identity of human PD-Iα with human autotaxin (ATX), with the exception of another likely alternatively spliced sequence present in melanoma-derived autotaxin (Fig. 1, 52 aa). Using this information, we suggest that p421.HB represents an alternatively spliced isoform of PD-Iα. We refer to the PD-Iα isoforms as p421.HB/PD-Iα. Common structural features of p421.HB/PD-Iα/ATX, PC-1 (van Driel and Goding, 1987; Buckley et al., 1990), and the gp130RB13–6 antigen (Deissler et al., 1995) define the somatomedin/phosphodiesterase family of proteins, which is characterized by the presence of two somatomedin B domains, a phosphodiesterase-active site, and an EF hand-like motif in the extracellular part of the proposed type II (cytoplasmic N terminus) membrane proteins.
p421.HB/PD-Iα is expressed predominantly in the CNS, in which expression increases toward adulthood with a peak around postnatal day 20
Northern blot analyses were performed to characterize the tissue-specific and developmental expression of p421.HB/PD-Iα (Fig. 2). As shown for rat brain-specific PD-Iα (Narita et al., 1994), the p421.HB/PD-Iα cDNA hybridized to an mRNA of ∼3.3 kb. In the adult, p421.HB/PD-Iα mRNA was expressed predominantly in the CNS (brain and spinal cord) with additional signals detectable especially in heart, lung, and spleen. The lower molecular weight band in adult liver might be explained by hybridization to another, yet unidentified, PD-Iα isoform, or it may result from cross-hybridization with a homologous mRNA, possibly coding for another member of the somatomedin/phosphodiesterase protein family. Highest expression within the adult CNS was observed in areas enriched in oligodendrocytes (spinal cord and brainstem but not frontal cortex). The high levels of p421.HB/PD-Iα mRNA in adult cerebellum are likely to be derived from choroid plexus epithelial cells present in the tissue used for RNA isolation (Fig. 3). During rat brain development, p421.HB/PD-Iα was expressed by postnatal day 5, and expression increased toward adulthood with an intermediate peak around postnatal day 20, when active myelination takes place.
p421.HB/PD-Iα mRNA is expressed in oligodendrocytes and choroid plexus epithelial cells
In situ hybridization was performed to determine the cellular source of p421.HB/PD-Iα mRNA during development of the CNS. In the spinal cord p421.HB/PD-Iα mRNA-positive cells showed a distribution similar to cells positive for PLP mRNA, coding for the major myelin protein of the CNS (Fig. 3, compare A–C withD–F). At postnatal day 4, p421.HB/PD-Iα-positive cells were detectable ventrally, close to the spinal cord surface (Fig.3A) and in the dorsal column (not shown). In 21-d-old rat spinal cord the number of p421.HB/PD-Iα mRNA-expressing cells was increased, and these cells were found in white as well as in gray matter (Fig. 3B). Expression of p421.HB/PD-Iα mRNA appeared to decrease toward adulthood, with only a few p421.HB/PD-Iα mRNA-positive cells being detectable (Fig. 3C, arrows). In the brain of 21-d-old rats p421.HB/PD-Iα mRNA-positive signals were obtained in all white matter areas [cerebellum (Fig.3G–I); corpus callosum, fimbria, and fornix (data not shown)]. In contrast to the spinal cord, however, no p421.HB/PD-Iα signals were detectable at postnatal day 4 in white matter areas of the brain, although differentiating oligodendrocytes could already be identified by PLP expression (Fig. 3, compareG and K). As in the spinal cord, the number of p421.HB/PD-Iα mRNA-positive cells in white matter was higher in postnatal day 21 than in adult brain, where only a few positive cells were visible (Fig. 3I, arrows). The distribution and developmental regulation of p421.HB/PD-Iα mRNA-positive cells in the CNS suggests that these cells are oligodendrocytes.
To establish this interpretation more conclusively, we performedin situ hybridization of cultured cells enriched for oligodendrocytes with a p421.HB/PD-Iα cRNA probe in combination with immunostaining for the oligodendrocyte-specific enzyme CNP (Fig.4). The presence of double-labeled cells clearly demonstrates that p421.HB/PD-Iα mRNA is expressed in differentiated oligodendrocytes, which express the earliest known myelination-specific protein, CNP. However, under the cell culture conditions used, only ∼10% of the CNP-positive cells were p421.HB/PD-Iα mRNA-positive, and p421.HB/PD-Iα mRNA expression levels of these oligodendrocytes were relatively low when compared with PLP (data not shown). These experiments also showed that the few astrocytes in these cultures were negative for p421.HB/PD-Iα mRNA (also see RT-PCR data in Fig. 5). Because CNP expression is not restricted to one well defined developmental stage of the oligodendrocyte lineage, additional studies are necessary to more exactly define the time course of p421.HB/PD-Iα mRNA expression during the process of differentiation from an A2B5-positive oligodendrocyte progenitor cell to a myelinating oligodendrocyte.
In addition to expression by oligodendrocytes, p421.HB/PD-Iα mRNA was detected in the choroid plexus, with increasing levels of expression during development (see choroid plexus of the ventral ventricle in Fig.3N–P). The cells of the choroid plexus could be identified as choroid plexus epithelial cells by combining immunofluorescence (Glut 1) and in situ hybridization (p421.HB/PD-Iα) (data not shown). These data also showed that p421.HB/PD-Iα is not expressed in ependymal cells lining the ventricles.
p421.HB/PD-Iα mRNA is expressed in at least four isoforms, of which two appear to be expressed exclusively in the CNS
As discussed earlier (Fig. 1), homologies between the sequences of rat PD-Iα (Narita et al., 1994) and the cDNA clone p421.HB suggested that p421.HB represents an isoform of rat brain-specific PD-Iα most likely generated by alternative splicing. To demonstrate the existence of the two predicted p421.HB/PD-Iα isoforms, we performed RT-PCR using two pairs of oligonucleotides and RNA from different rat tissues, as well as from brains of animals of different developmental ages (Fig. 5). Subsequently the RT-PCR products were cloned and sequenced. In the adult, only RNA from the CNS yielded amplification products of 309 and 297 bp, both of which contained the putative 75 bp exon, missing in p421.HB and the published sequences of human autotaxin (Figs. 1, 5, compare A, adult lane, withB). In contrast, the shorter isoforms of p421.HB/PD-Iα (222 and 234 bp) appeared to be expressed more ubiquitously (Fig.5B). In addition to the proposed 75 bp exon, a second presumably alternatively spliced sequence of 12 bp was identified, giving rise to amplification products of 297 and 222 bp in length. The encoded amino acids of the proposed 12 bp alternatively spliced exon are located 17 amino acids N-terminal to the proposed 75 bp exon and are present in all yet published cDNA sequences coding for p421.HB/PD-Iα/autotaxin. This sequence of 12 bp does not seem to be expressed in any unique tissue- or age-specific manner. During development, the brain-specific 75 bp sequence seemed to be regulated similarly to the entire p421.HB/PD-Iα mRNA (Fig. 5A; and Northern blot using the 75 bp sequence as probe, data not shown). These data suggest that the 75 bp sequence was expressed only in the CNS, but these experiments could not distinguish between expression in oligodendrocytes and in choroid plexus epithelial cells. Detailed, more quantitative analyses of additional RT-PCR data showed that in a CNS area devoid of choroid plexus epithelial cells and enriched for oligodendrocytes (optic nerve) the brain-specific isoforms were abundantly expressed, whereas in the adult choroid plexus the CNS-specific isoforms were present at a very low percentage (Fig.5C). In addition, cultured astrocytes did not express p421.HB/PD-Iα mRNA (Fig. 5D; very faint bandslikely resulted from a few remaining oligodendrocytes in these shaken cultures). In contrast, mixed glial cultures and purified oligodendrocytes expressed all four isoforms [Fig. 5D; the additional band above the 234 bp bandresulted from heteroduplex formation, as demonstrated by reannealing experiments (Wenger et al., 1991) (data not shown)]. In summary, these data suggest that the oligodendrocyte is the predominant cell type expressing the 75 bp CNS-specific sequence.
p421.HB/PD-Iα mRNA levels are decreased in the CNS of the dysmyelinating mutant jimpy
To assess the functional involvement of p421.HB/PD-Iα in oligodendrocyte differentiation and myelination, we analyzed p421.HB/PD-Iα mRNA levels in the dysmyelinating mutantsjimpy, shiverer, and trembler by RPA (Fig. 6). Jimpy animals are characterized by a point mutation in the gene coding for PLP, which results in the failure of oligodendrocyte precursors to differentiate into mature oligodendrocytes. The shiverer mutation results from a deletion of a large portion of the myelin basic protein gene and in these mice oligodendrocytes begin to myelinate, but they fail to form normally compacted myelin. In addition to these CNS dysmyelinating mutants, we investigated p421.HB/PD-Iα mRNA levels in the CNS of thetrembler mutant, in which a point mutation in the gene coding for the peripheral myelin protein 22 results in severe hypomyelination by Schwann cells but is without described effects on oligodendrocytes in the CNS. Animals at postnatal day 21 were selected for these experiments because of the presumed normal peak of p421.HB/PD-Iα mRNA expression in oligodendrocytes (Fig. 3). Injimpy brains and spinal cords a pronounced decrease in p421.HB/PD-Iα mRNA levels was observed, whereas changes inshiverer and trembler mutants appeared to be statistically insignificant. Because the trembler mutation is described to affect the PNS only, normal levels of p421.HB/PD-Iα mRNA in the CNS were anticipated. Normal levels of p421.HB/PD-Iα mRNA in the shiverer CNS suggest that p421.HB/PD-Iα plays a functional role at a developmental time point before myelin compaction. In that case, expression of p421.HB/PD-Iα would be significantly affected in jimpy mice but less so in shiverermice.
p421.HB/PD-Iα mRNA levels are reduced at early onset of clinical symptoms in a relapsing EAE model
Because p421.HB/PD-Iα is potentially important during myelin sheath formation, studies were begun to investigate its expression in a second type of animal model with white matter pathology, EAE, in which myelin damage is accompanied by an infiltration of inflammatory cells and changes in cytokine levels. EAE was induced with the immunodominant determinant of PLP (p139–151) in (SWR/SJL) F1 mice, causing a relapsing–remitting disease with a progression to chronic disability (Yu et al., 1996). p421.HB/PD-Iα mRNA levels were determined at onset of clinical symptoms, at which, histologically, myelin appears to be normal, but infiltration of inflammatory cells results in an increase of various chemokines, such as interferon-γ-inducible protein and monocyte chemoattractant protein-1 (Glabinski et al., 1995). In both CNS areas, brain and spinal cord, an ∼25% reduction in mRNA levels coding for p421.HB/PD-Iα was observed (Fig. 7). No extensive changes in p421.HB/PD-Iα mRNA levels in the choroid plexus were noted byin situ hybridization, although further quantitative analyses are needed to confirm this. A similar reduction in mRNA levels in both CNS regions was found for PLP, the major myelin protein of the CNS (Fig. 7). These data indicate that the reduced p421.HB/PD-Iα mRNA levels result from alterations in oligodendrocyte gene expression. The observed changes in oligodendrocyte mRNA levels in both brain and spinal cord and the fact that for the EAE model used in this study infiltration of cells of the immune system and demyelination at later stages of the disease occur predominantly in the spinal cord (Sobel et al., 1991), suggest a broader oligodendrocyte response than just at the site of inflammatory infiltration. In conclusion, these data indicate that during infiltration of lymphocytes, before any signs of demyelination are obvious, oligodendrocyte gene expression changes, possibly rendering these cells more susceptible for a subsequent autoimmune attack.
DISCUSSION
p421.HB/PD-Iα represents a member of the somatomedin/phosphodiesterase family of proteins that is expressed predominantly in the CNS by oligodendrocytes, the myelin-forming cells of the CNS, and by choroid plexus epithelial cells. The tissue-specific expression of rat p421.HB/PD-Iα described here is in good agreement with results published by Narita et al. (1994) and Lee et al. (1996). In addition, our detailed developmental analysis in the CNS revealed an intermediate peak of expression around the time of active myelination. Furthermore, p421.HB/PD-Iα expression in the spinal cord is consistent with the postnatal expression of myelin-specific glycolipids and myelin basic protein, which are first observed most ventrally and closest to the spinal cord surface in the white matter, and then later in a patchy pattern in the gray matter, following the presumptive spatio-temporal myelination pattern of fiber tracts (Jordan et al., 1989; Schwab and Schnell, 1989). These findings, together with the demonstration of p421.HB/PD-Iα mRNA expression in differentiated oligodendrocytes in culture, strongly suggest a role of p421.HB/PD-Iα in oligodendrocyte maturation and/or myelination.
Considering the possible function of p421.HB/PD-Iα expressed by oligodendrocytes, its function in epithelial cells of the choroid plexus is rather obscure. The choroid plexus represents the main source of the CSF, the composition and production of which were shown to be regulated by adenosine (Kalaria and Harik, 1986; Faraci et al., 1988). p421.HB/PD-Iα together with ecto-5′-nucleotidase (Braun et al., 1994) could very well be involved in these regulatory events, which might be essential for the maintenance of body fluid–brain barriers. Interestingly, PD-Iα mRNA was also localized in ciliary epithelial cells, iris pigment epithelial cells, and retinal pigment epithelial cells, suggesting a common functional role in secretory epithelial cells (Narita et al., 1994). In addition, it has been suggested that choroid plexus epithelial cells are producing target-derived neurotrophic factors for innervating neurons, such as NGF, neurotrophin 4, and insulin-like growth factor II (Hynes et al., 1988; Timmusk et al., 1995), which would be consistent with a putative cytokine function for p421.HB/PD-Iα, as described for its human homolog autotaxin. Expression of a variety of cytokines by choroid plexus epithelial cells might also provide a pool of survival and regulatory factors that could insure maintenance of proper CNS function.
Differential expression of p421.HB/PD-Iα isoforms, most likely generated by alternative splicing, complicates interpretation of mRNA and protein expression data. Our studies identified four isoforms of p421.HB/PD-Iα. In addition, sequence analysis indicates the possible existence of yet more variants (see Fig. 1). At the present time, it is unclear what functional consequences any of these alternative splicing events may have, although it appears that the 25 amino acid PD-Iα-specific sequence is expressed predominantly in oligodendrocytes and may, therefore, be crucial for p421.HB/PD-Iα function during myelination. Interestingly, the 75 bp CNS-specific sequence appears to be more enriched in the optic nerve than in oligodendrocytes in culture, either reflecting a unique property of the optic nerve or demonstrating a downregulated expression of this sequence in vitro, possibly induced by altered cell–cell contact, such as between oligodendrocytes and axons.
Decreased levels of p421.HB/PD-Iα mRNA in jimpy brains, demonstrated here by RPA, were confirmed by in situhybridization, where we observed a decreased number of p421.HB/PD-Iα mRNA-positive cells in white matter (B. Fuss, E. Shick, and W. B. Macklin, unpublished observations). These data suggest thatjimpy oligodendrocytes, which remain immature, with increased rates of oligodendrocyte precursor cell proliferation and oligodendrocyte cell death (Skoff, 1995), cannot differentiate to the developmental stage at which p421.HB/PD-Iα is normally expressed. From these studies we propose that expression of p421.HB/PD-Iα is important for the intermediate stages of oligodendrocyte differentiation and/or early events involved in the formation of the myelin sheath, before myelin compaction. As an important future question, it remains to be seen whether the proposed functional role in myelination is related to the hypothesized functional properties of the protein in cell–cell and/or cell–extracellular matrix interactions (see above and below).
Downregulation of p421.HB/PD-Iα and PLP expression in the CNS at early stages of EAE suggests an impairment of oligodendrocyte function before detectable damage of the myelin sheath. These conclusions are supported by data obtained in a virus-induced animal model for multiple sclerosis, in which inoculation of susceptible strains of mice with Theiler’s encephalomyelitis virus (TMEV) induces inflammatory demyelination (Rodriguez et al., 1994). Downregulation of PLP mRNA in the spinal cord was observed preceding the development of prominent inflammation and demyelination in susceptible but not TMEV-resistant mice. These data suggest that oligodendrocyte damage caused by several different initiating events may begin with changes in myelin gene expression before lesions can be detected morphologically. These changes in gene expression could be induced by soluble factors synthesized either by infiltrating cells directly or by activated cells of the nervous system, such as astrocytes or microglia. Interestingly, it has been recently reported that autotaxin mRNA levels are downregulated after interferon-γ treatment (Santos et al., 1996). Together with the identification of interferon-γ receptors on oligodendrocytes (Torres et al., 1995) and a proposed role of interferon-γ in the pathogenesis of demyelinating diseases through a direct effect on oligodendrocytes (Vartanian et al., 1995; Agresti et al., 1996), interferon-γ represents a possible candidate cytokine that could be responsible for the above-described changes in oligodendrocyte gene expression. It must be noted, however, that we cannot exclude the possibility that the observed downregulation of p421.HB/PD-Iα in the brains of EAE mice results, at least in part, from changes in choroid plexus epithelial cells. On the other hand, the data demonstrating a comparable downregulation in the spinal cord both for p421.HB/PD-Iα and PLP mRNA argue for likely effects on oligodendrocyte gene expression in this model.
With regard to possible mechanisms of p421.HB/PD-Iα function, it is worth mentioning that the second somatomedin B domain of p421.HB/PD-Iα, but not PC-1 or the gp130RB13–6 antigen, contains an RGD peptide sequence, which represents a binding site for several (α5β1, αIIbβ3, and all or most αvβ integrins) but not all integrin receptors (Hynes, 1992). Integrins have been identified in cultured oligodendrocytes, although the nature of the integrin subunits expressed by oligodendrocytes remains controversial (Cardwell and Rome, 1988;Malek-Hedayat and Rome, 1994; Milner and French-Constant, 1994). Therefore, p421.HB/PD-Iα could represent an extracellular matrix ligand regulating oligodendrocyte function. On the other hand, because the primary function for the human homolog of p421.HB/PD-Iα, autotaxin, appears to be in motility (Stracke et al., 1993), p421.HB/PD-Iα may very well be involved in motility and/or oligodendrocyte process extension during oligodendrocyte differentiation and identification of axons to be myelinated. In addition to the potential interaction of the p421.HB/PD-Iα protein with integrins, the EF hand-like motif at the far C-terminal end suggests that its functional properties may be regulated by Ca2+ binding. Although EF hand motifs are well known as paired domains of many Ca2+-binding intracellular proteins, such as calmodulin and parvalbumin (Babu et al., 1988), single EF hand-like motifs have been described in extracellular proteins as well. In SPARC/BM-40/osteonectin the embedding of the single EF hand motif into a larger domain was shown to be necessary for Ca2+-dependent binding to collagen IV (Maurer et al. 1995). At the present time, it is not known, whether p421.HB/PD-Iα binds to collagen IV or any other brain matrix proteins. However, such studies are clearly relevant for understanding the role of p421.HB/PD-Iα in normal brain development and under pathological conditions.
The present study provides good evidence that p421.HB/PD-Iα in the CNS is likely to be involved in oligodendrocyte function. In the process of oligodendrocyte maturation and/or myelin sheath formation, it may be involved in cell–cell and/or cell–extracellular matrix interactions. It will be important to establish whether different functional properties of p421.HB/PD-Iα require the expression of different isoforms and to what extent expression of one or several of these isoforms plays a critical role in the ability of the oligodendrocyte to myelinate and remyelinate CNS axons.
Footnotes
This work was supported by Grants from the National Multiple Sclerosis Society (W.B.M. and V.K.T.) and National Institutes of Health (V.K.T.) and by postdoctoral fellowships from the National Multiple Sclerosis Society (H.B. and B.F.). We thank Justin Johnson for technical assistance, Dr. J. Drazba for assistance with confocal microscopy, and Dr. A. Nishiyama for helpful and encouraging discussions and critically reading this manuscript.
Correspondence should be addressed to Dr. Babette Fuss, The Cleveland Clinic Foundation, Department of Neurosciences, NC-3, 9500 Euclid Avenue, Cleveland, OH 44195.