Proteolipid Protein Gene Product Can Be Secreted and Exhibit Biological Activity during Early Development

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The Journal of Neuroscience, March 15, 1999, 19(6):2143-2151

Proteolipid Protein Gene Product Can Be Secreted and Exhibit Biological Activity during Early Development
Masahisa Yamada¹, Anna Ivanova¹, Yoshihide Yamaguchi¹, Marjorie B. Lees², and Kazuhiro Ikenaka¹
¹ Laboratory of Neural Information, National Institute for Physiological Sciences, Okazaki National Research Institutes, Aichi 444-8585, Japan, and ² Biochemistry Division, E. K. Shriver Center, Waltham, Massachusetts 02254

  ABSTRACT

Top
Abstract
Introduction
References

A gene encoding myelin proteolipid protein (PLP) and its smaller isoform DM20 is expressed at least 1 week before myelination.Mutations within the gene cause abnormalities in the developmentof premyelinating oligodendrocytes, resulting in hypomyelinatingdisorders. These findings suggest a premyelinating function ofthe PLP gene products. We previously demonstrated that PLP geneexpression is directly associated with secretion of a factor thatincreases the number of oligodendrocytes. Here we show that thisactivity is mediated by a secreted fragment containing the C-terminalportion of PLP. This factor increased the bromodeoxyuridine incorporationrate in both oligodendrocyte and astrocyte lineage cells; a syntheticpeptide (PLP 215-232) exhibited a similar activity. Dose-responsecurves of PLP and PLP peptide showed maximum activities at a concentrationin the picomolar range, which decreased at higher concentrations.These observations demonstrate that a secreted PLP gene productexerts biological activity at a premyelinating stage before themajor induction of thegene.

Key words: oligodendrocyte development; myelin proteolipid protein; DM20; differentiation factor; myelin; cell culture

  INTRODUCTION

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Abstract
Introduction
References

Myelin proteolipid protein (PLP) is one of the major proteins in CNS myelin and may function in stabilizing the myelin membrane.However, in many PLP mutants an abnormal phenotype is evidentbefore the myelinating period (for review, see Skoff and Knapp,1992). The abnormalities include early degeneration of oligodendrocytes,the myelin-forming cells in the CNS, cellular abnormalities inastroglia (Skoff, 1976), and increased axonal proteolysis (Nixon,1982). Thus, mutations in the PLP gene seemed to exert pleiotropiceffects on the development of the nervous system. Although proteinsfor PLP or its alternatively spliced variant, DM20, are foundpostnatally at a late stage of oligodendrocyte development (Levineet al., 1990), DM20 mRNA is found at early stages before myelination(Ikenaka et al., 1992; Timsit et al., 1992). The amino acid sequenceof PLP is totally conserved among rat, mouse, and human (Mikoshibaet al., 1991); even a point mutation or a slight overexpressionof the PLP gene causes severe effects on oligodendrocyte survival(Hudson and Nadon, 1992; Knapp, 1996). The jimpy mouse, one ofthe PLP mutants, splices out the fifth exon from the PLP mRNA(Nave et al., 1986; Moriguchi et al., 1987). Jimpy oligodendrocytesin culture, which normally degenerate, can survive and producemyelin membrane-like sheets after the addition of normal, butnot jimpy, astrocyte conditioned medium (Bartlett et al., 1988;Knapp et al., 1992). This suggested that PLP gene expression maybe related to the secretion of humoral factor(s) that influencematuration and survival of oligodendrocytes. Furthermore, a partialrescue of jimpy oligodendrocytes was observed when embryonic jimpybrain fragments were transplanted into brains expressing a wild-typePLP gene (Lachapelle et al., 1991). Finally, the number of oligodendrocytespresent in mixed glial cell cultures containing conditioned mediafrom cell lines expressing the PLP gene (G26 mouse oligodendroglioma,B104 rat neuroblastoma, and B16 mouse melanoma) (Ikenaka et al.,1992) was significantly higher than that of control cultures withoutconditioned media or those supplemented with conditioned mediumfrom NIH3T3 fibroblasts, which do not produce DM20 (Nakao et al.,1995). However, when NIH3T3 cells were modified to produce PLPor DM20, the cells secreted a factor [which is neither platelet-derivedgrowth factor (PDGF) nor basic fibroblast growth factor (bFGF)]that increased the number of oligodendrocytes (Nakao et al., 1995).Taken together, these findings indicated that the expression ofthe PLP gene is sufficient for, and directly associated with,the secretion of a factor that influences oligodendrocytedevelopment.

In the present study we demonstrate that a portion of PLP/DM20 is directly secreted into the medium in vitro and displaysbiological activity against oligodendrocytes and astrocytes. Furthermore,a synthetic peptide corresponding to PLP 215-232 was able to reproducethe activity found in the conditioned media of PLP/DM20-producingcells. A biological effect of the PLP fragment was observed atextremely low concentrations (0.3 pM). Therefore, although PLPgene expression in embryonic brain is very low and can only bedetected by RT-PCR or in situ hybridization, the possibility ofa function for PLP/DM20 in the embryonic brain isproposed.

  MATERIALS AND METHODS

Materials. ICR mice were obtained from Nihon SLC (Hamamatsu, Japan). Monoclonal anti-galactocerebroside antibody (O1, mouseIgM) (Sommer and Schachner, 1981; Bansal et al., 1989) was a giftfrom Dr. Steve Pfeiffer (University of Connecticut, Storrs, CT).The peptides of PLP (residues 209-217, 215-232, and 264-276) weresynthesized in the laboratory of Dr. Richard Laursen (Departmentof Chemistry, Boston University, Boston, MA) or obtained fromPeptide Institute (Osaka,Japan).

Cell line cultures and conditioned media. Previously we established PLP- or DM20-producing NIH3T3 fibroblast cell lines usingretrovirus (Nakao et al., 1995). PLP- or DM20-producing NIH3T3cells were maintained in DMEM (Life Technologies, Gaithersburg,MD) with 10% fetal bovine serum (FBS; ICN Biochemicals, CostaMesa, CA; lot 10508092). After 48 hr, medium was changed to serum-freechemically defined N4 medium (Bottenstein et al., 1988). G26 mouseoligodendroglioma (Sundarraj et al., 1975), B104 rat neuroblastoma(Schubert et al., 1975), and B16 mouse melanoma (Hu and Lesney,1964) cells were maintained in a 1:1 mixture of DMEM and Ham'sF-12 medium supplemented with 10% FBS. Cells were plated at 60%confluence; after 12 hr medium was changed to serum-free chemicallydefined N4 medium. After a further 24 hr, 1 µg/ml phenylmethylsulfonylfluoride was added to the conditioned media from the cell lines.Cell debris was removed by brief centrifugation. The supernatantswere further concentrated as described previously (Nakao et al.,1995). The samples were aliquoted and stored at $-$ 70°C. Proteinconcentration was determined using a Bio-Rad (Hercules, CA) proteinassay with bovine serum albumin as astandard.

Preparation of purified PLP and PLP peptides. PLP was solubilized in a detergent [first in Triton X-100 and finally in 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonicacid (CHAPS)] and purified from mouse cerebella as described previously(Yamaguchi et al., 1996), and gave a single band on SDS-PAGE stainedwith a Silver Stain II kit (Wako Chemicals, Neuss, Germany). Proteinconcentration was estimated by Bio-Rad protein assay and confirmedby amino acid analysis after gas phase acidhydrolysis.

Lyophilized PLP peptides were dissolved in 15 mM HCl. Stock solutions (10 mg/ml) were stored at $-$ 80°C. For the experimentthey were diluted with O3/N4 defined medium (see Primary mouseglial cell culture) and added to the glial cellcultures.

Primary mouse glial cell culture. Neuroglial cells were isolated from embryonic day 17 (E17) cerebral hemispheres of ICR mice.Dissociated mixed glial cell cultures were prepared as describedbefore (Nakao et al., 1995). The dissected tissue was cut intopieces with scalpels and shaken for 15-20 min at 37°C in Ca²⁺- and Mg²⁺-free PBS containing 0.25% bovine pancreatic trypsin (Difco, Detroit,MI), 0.5% glucose (Sigma, St. Louis, MO), and 50 µg/ml DNase I(Boehringer Mannheim, Indianapolis, IN). After trypsinization,the cells were dissociated in DMEM (Life Technologies) containing10% FBS (Life Technologies) by gentle pipetting through a flame-polishedPasteur pipette. The cells were then plated on polyethylenimine-coatedplastic disks (9 mm in diameter; Aclar) at a density of 3 × 10⁵/cm² in 10 cm Petri dishes. After the cells attached to the disks,10 ml of 10% FBS-containing DMEM were added to the dish. After3 d in vitro (3 DIV) the disks were randomly transferred into3.5 cm dishes (six disks per dish) containing 3 ml of a serum-freechemically defined medium (2:1 mixture of N4/O3 media; Bottensteinet al., 1988), allowed to grow for a further 4 d, and processedfor immunostaining. Conditioned media from NIH3T3 cells engineeredto produce PLP/DM20, purified PLP/DM20, or synthetic peptideswere added together with the chemically defined medium at E17+ 3 DIV. The control disks, either untreated or treated with solvent,were processed in parallel with experimental disks. We alwaysobserved some difference in basal numbers of galactocerebroside(GalC)-positive cells in primary mixed glial cell cultures after7 DIV, but it did not alter the effect of PLP/DM20 on the GalC-positivecells.

We have routinely used primary cultures prepared from E17 mouse cerebral hemispheres, began treatment after 3 DIV correspondingto postnatal day 1 (P1), and counted GalC-positive cells aftera further 4 DIV corresponding to P5. In some cases we preparedthe cells from E17 and P2 mouse cerebral hemispheres simultaneouslyand processed them in parallel. Thus, we could compare effectsof purified PLP/DM20 or the PLP peptides in the two cultures:one corresponding to P5 and another toP9.

Immunostaining. To assess the number of GalC-positive cells, plastic disks with live cells were incubated with monoclonalmouse anti-GalC antibody, O1, for 30 min at 37°C. The disks werewashed three times and fixed with 4% paraformaldehyde for 10 min.The cell cultures were treated with fluorescein-conjugated goatanti-mouse IgM (1:200; Cappel, West Chester, PA) for 1 hr at roomtemperature and examined and counted under an Olympus Optical(Tokyo, Japan) Vanox-S fluorescencemicroscope.

Preparation of the AA3 and AH7-2a antibodies, neutralization, and immunoabsorbtion experiments. Production of AA3 and AH7-2amonoclonal antibodies and hybridoma was described previously (Yamamuraet al., 1991). The AA3 and AH7-2a antibodies were purified usinga general ammonium sulfate precipitationmethod.

In neutralization experiments, anti-PLP monoclonal antibodies (AA3 and AH7-2a) were incubated with the samples (purified PLP/DM20or supernatants from PLP/DM20-transformed cells) at 4°C for 60min and added to the serum-free chemically defined medium. Duringthe next 4 d the medium was not changed. The cells were immunostained4 d after addition of the samples, corresponding to P5, and thetotal number of GalC-positive cells was counted at least on thethree different disks per eachpoint.

In immunoabsorption of samples with protein G-Sepharose, 1 mg each of the IgG fractions was dissolved in binding buffer (0.5M acetate buffer, pH 4.6, containing 1.5 M NaCl) and added to200 µl of protein G-Sepharose suspension (Sigma). The solutionswere incubated for 18 hr at room temperature on a rotator. Afterthe incubation, each solution was poured into a column and thenwashed with a serum-free chemically defined medium (see Primarymouse glial cell culture). The washed gel was transferred intoa tube and incubated with 30 µg/ml enriched supernatant from DM20-producingNIH3T3 cells for 18 hr at 4°C on a rotator. After incubation sampleswere filtered through a 0.22 µm filter and added to the primarymouse mixed glial cellculture.

Bromodeoxyuridine immunohistochemistry on mixed glial cell culture. To study the growth of oligodendrocyte progenitors inserum-free culture conditions, bromodeoxyuridine (BrdU) labelingreagent (Amersham, Arlington Heights, IL) was added 2 d afterintroducing samples into mixed glial cell culture (5 DIV). Cellswere cultured in the presence of BrdU for 24 hr. After BrdU treatment,the cell cultures were washed with defined medium and transferredto a BrdU-free medium for 1 more day (until 7 DIV). Double labelingimmunocytochemistry was performed using anti-BrdU and anti-GalCor anti-GFAPantibodies.

Living cells on the disks were incubated with O1 antibody, followed by rhodamine-conjugated goat anti-mouse IgM (µ chain specific,1:50; Cappel). The disks were washed three times with PBS (Mg²⁺ and Ca²⁺ free), fixed with acid-ethanol for 10 min, and then treated withDNase I and anti-5-bromo-2'-deoxyuridine antibody (Amersham) for1 hr at room temperature. Incorporated BrdU was detected by immunofluorescenceusing FITC-conjugated goat anti-mouse IgG (Vector Laboratories,Burlingame,CA).

Cell count. We counted the total number of GalC-positive cells on at least three different disks per each point. The numberof GalC-positive cells in three experimental and three controldisks was compared with an unpaired one-tailed t test (p < 0.05)using Microsoft (Redmond, WA) Excel software from Microsoft Office98. An average of three disks was counted per each group. Thenumber of GalC-positive cells from the three control disks wastaken as 100%. Error bars represent SDs. Each experiment was repeatedat least three times, but here we present only one representativeset of data for each experiment. Cell count was blind; i.e., theperson counted the cell number without being informed of the natureofexperiments.

  RESULTS

The activities of enriched supernatants from PLP/DM20-producing NIH3T3 fibroblast cells were completely inhibited by anti-PLP antibody

When NIH3T3 fibroblasts were engineered to produce either PLP or DM20 mRNA, these cells began to secrete a factor that wasable to increase the number of GalC-positive cells in primaryglial cell cultures (Nakao et al., 1995). To examine the possibilitythat the expression of PLP/DM20 results in the secretion of PLPand DM20 themselves or their fragments, a monoclonal antibodyto PLP/DM20 (AA3) recognizing the C terminus of PLP/DM20 (Fig.1) was added to the cultures. Incubation of the supernatants fromthe PLP/DM20-producing fibroblasts with 10 µg/ml AA3 antibodyfor 60 min before its addition to the chemically defined mediumcompletely inhibited activity of the supernatants (Fig. 2). Antibodyalone did not affect the appearance of GalC-positive cells (Fig.2, bar 2). These findings suggest that PLP/DM20 itself or a fragmentcontaining the C-terminal region is released into the culturemedium and increases the number of oligodendrocytes.

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Figure 1. Current model of the topology of PLP in the plasma membrane of mature oligodendrocytes (Weimbs and Stoffel, 1992). However, nothing is known about structure of PLP during oligodendrocyte development. Positions of synthetic PLP peptides and antibody-binding sites are indicated. The C-terminal portion of the molecule secreted into the medium is marked by a square.

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Figure 2. Effect of anti-PLP monoclonal antibody (AA3) on the activity of PLP- or DM20-enriched supernatants (sup). Conditioned media from PLP or DM20-producing cells were enriched as described previously (Nakao et al., 1995). These enriched samples (30 µg/ml total protein concentration) were preincubated with AA3 antibody at 4°C for 60 min and added to the chemically defined medium. The mixture was applied to cell culture and kept for 4 d without medium change, and then the cells were fixed and immunostained for O1 antibody recognizing GalC. Bar 1, Enriched conditioned media from NIH3T3 cells containing pDL⁺ retrovirus vector without cDNA inserts (CONT, control); bar 2, 10 µg/ml AA3 antibody; bar 3, enriched conditioned media from DM20-producing NIH3T3 cells; bar 4, enriched conditioned media from DM20-producing NIH3T3 cells together with 10 µg/ml AA3 antibody; bar 5, enriched conditioned media from PLP-producing NIH3T3 cells; bar 6, enriched conditioned media from PLP-producing NIH3T3 cells together with 10 µg/ml AA3 antibody. Cells were immunostained for O1 antibody recognizing GalC. The total number of GalC-positive cells was counted on three different disks. Mean values of three control disks (69.6 cells per disk) had been taken as 100 percent. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05).

Purified PLP and DM20 increase the number of oligodendrocytes

To address more directly whether PLP or DM20 increases the number of oligodendrocytes, highly purified PLP isolated from aP2/P3 membrane fraction of ddY mouse cerebella (Yamaguchi et al.,1996) was added to mixed glial cell cultures in place of conditionedmedia (during the purification procedure PLP was separated fromDM20). After 4 d in vitro in the presence of purified PLP, thenumber of GalC-positive cells was increased twofold in a dose-dependentmanner up to 10 pg/ml (Fig. 3A), whereas higher concentrationsof protein reduced the activity. The detergent (CHAPS) used tosolubilize PLP had no effect on the number of GalC-positive cellsat the concentration used (data not shown). The activity of thepurified PLP at 10 pg/ml was completely inhibited by incubationwith 1.25-2.5 µg/ml AA3 before addition to the cell culture (Fig.3B). AA3 antibody alone did not influence the number (Fig. 3B)or morphology (data not shown) of oligodendrocytes.

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Figure 3. Effect of purified PLP and partially purified DM20 on the number of oligodendrocytes. A, Purified PLP was added to the mixed glial cell culture, and the number of GalC-positive cells was counted. Open circle, Control culture without PLP. Cells were immunostained for O1 antibody recognizing GalC. The total number of GalC-positive cells was counted on three different disks. Mean value of three control disks (77.6 cells per disk) had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05). B, Effect of purified PLP and monoclonal antibody AA3 on the number of GalC-positive cells. Mixed glial cell cultures were grown in the presence of purified PLP or PLP preincubated with AA3 antibody for 4 d, and then the cultures were fixed, and the number of GalC-positive cells were counted. Mean values of three control disks (61.1 cells per disk) had been taken as 100%. Error bars indicate SD. Bar 1, Defined medium (CONT); bar 2, 1.25 µg/ml AA3; bar 3, 10 pg/ml purified PLP; bar 4, 10 pg/ml purified PLP plus 1.25 µg/ml AA3; bar 5, 10⁴ pg/ml purified PLP; bar 6, 10⁴ pg/ml purified PLP plus 2.5 µg/ml AA3. C, Typical photographs of immunocytochemical staining of cultured oligodendrocytes using monoclonal O1 antibody (anti-GalC antibody). C1, Defined medium; C2, 10 pg/ml purified PLP; C3, 10⁴ pg/ml purified PLP; C4, 10 pg/ml purified PLP plus 2.5 µg/ml AA3; C5, 10⁴ pg/ml purified PLP plus 2.5 µg/ml AA3. Scale bar, 100 µm.

The increase in the number of GalC-positive oligodendrocytes in response to purified PLP was less prominent at concentrations>100 pg/ml (Fig. 3A,B, bar 5). To eliminate the possibility thatthis decreased activity was mediated by inhibitory factors contaminatingthe preparations, primary glial cell cultures were treated with10⁴ pg/ml purified PLP together with the AA3 antibody (2.5 µg/ml).The treatment resulted in an increase of GalC-positive cell number(Fig. 3B, bar 6, C). Therefore, the reduced activity of purifiedPLP at high concentrations was not mediated by the contaminationwith inhibitory factors, but rather by the properties of PLPitself.

The activity increasing the number of oligodendrocytes present in established neural cell lines is also mediated by PLP/DM20

We have previously shown that DM20 mRNA is produced in many neuronal cell lines (Ikenaka et al., 1992), and that a correlationcan be found between PLP gene expression by the cell lines andthe potency of the supernatants for increasing the number of oligodendrocytes(Nakao et al., 1995). To investigate the possible involvementof PLP/DM20 as an active element in these supernatants, AA3 monoclonalantibody (10 µg/ml) was added to the assay system. The numberof GalC-positive cells was examined after incubation of the mixedglial cultures for 4 d in O3 defined medium containing 33% supernatantsfrom G26, B104, and B16 cell lines (Fig. 4). Supernatants fromG26, B104, and B16 cell lines increased the number of GalC-positivecells sixfold, threefold, and twofold of the control level, respectively(Fig. 4, bars 3, 5, 7). Pretreatment with AA3 antibody significantlyinhibited this activity in the supernatants (Fig. 4, bars 4, 6,8). These results suggest that the expression of the PLP genein established neuronal cell lines resulted in secretion of PLP/DM20or its fragment into the medium, which in turn, could increasethe number of oligodendrocytes in culture.

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Figure 4. Effect of the conditioned media (CM) obtained from G26, B104, and B16 cell lines and AA3 antibody on the number of GalC-positive cells. Mixed glial cells were cultured in a mixture of CM and chemically defined medium O3/N4 in a ratio of 1:2. AA3 antibody was incubated with CM for 60 min at 4°C before addition to the defined medium, and the cells were cultured in the mixture for 4 d without medium change. Mean value of three control disks (51.6 cells/mm²) had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05). Bar 1, Chemically defined medium (CONT); bar 2, 10 µg/ml AA3; bar 3, CM from G26 cells; bar 4, CM from G26 cells plus 10 µg/ml AA3; bar 5, CM from B104 cells; bar 6, CM from B104 cells plus 10 µg/ml AA3; bar 7, CM from B16 cells; bar 8, CM from B16 cells plus 10 µg/ml AA3.

Enriched supernatants from NIH3T3 cells producing PLP or DM20 increased the number of BrdU-labeled oligodendrocytes and astrocytes

To investigate whether the factor increases the proliferation rate of progenitor cells, glial cultures were treated with enrichedsupernatants from PLP- or DM20-producing NIH3T3 cells and exposedto BrdU for 24 hr. As a control we used those from NIH3T3 cellsharboring retroviral vector without cDNA inserts. The enrichedsupernatants from both PLP- and DM20-producing cells increasedthe number of O1-positive cells incorporating BrdU as well asthe total number of O1-positive cells (twofold increase; Table1). Surprisingly, the total number of BrdU-labeled and GFAP-positivecells (the major cell population represented by astrocytes) alsoincreased approximately two fold. This indicates that the presenceof the PLP/DM20 or its fragment affects proliferation of variousglial cell types.


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Table 1. Supernatants from PLP/DM-20-producing cells promote gliogenesis in vitro

Structural analysis of the PLP gene products secreted into the culture medium

Purified PLP increased the number of oligodendrocytes (Fig. 3A). To examine whether DM20 can cause a similar effect, DM20partially purified and separated from PLP by column chromatography(Yamaguchi et al., 1996) was added to mixed glial cell cultures.The DM20 fraction significantly increased the number of oligodendrocytes(Fig. 5, bar 6). A purified proteolipid mixture containing PLPand DM20 isolated from adult ICR mouse brain by organic solventextraction (chloroform-methanol and ether-ethanol) (Monreal, 1975)also increased the number of oligodendrocytes (data not shown).These results demonstrate that both PLP and DM20 affect the oligodendrocytematuration and survival in a similar manner, and that correctfolding of PLP/DM20 may not be necessary for this activity.

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Figure 5. Enriched supernatant (sup.) from DM20-producing cells and partially purified DM20 were incubated with protein G-Sepharose resin coupled with AH7-2a-IgG, AA3-IgG, or normal rat IgG. The resins were poured into columns, and eluted fractions were collected and added to the primary cell cultures; the number of GalC-positive cells has been counted as described in Materials and Methods. Mean value of three control disks (72.7 cells per disk) had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05). Bar 1, 30 µg/ml (total protein content) enriched supernatant from NIH3T3 cells containing pDL⁺ retrovirus vector without cDNA inserts; bar 2, 30 µg/ml enriched supernatant from DM20-producing NIH3T3 cells; bar 3, 30 µg/ml fraction eluted from resins coupled with normal rat IgG loaded with enriched supernatant from DM20-producing NIH3T3 cells; bar 4, 30 µg/ml fraction eluted from resins coupled with AH7-2a IgG loaded with enriched supernatant from DM20-producing NIH3T3 cells; bar 5, 30 µg/ml fraction eluted from resins coupled with AA3 IgG loaded with enriched supernatant from DM20-producing NIH3T3 cells; bar 6, 100 pg/ml fraction eluted from resins coupled with normal rat IgG loaded with partially purified DM20; bar 7, 100 pg/ml fraction eluted from resins coupled with AH7-2a IgG loaded with partially purified DM20; bar 8, 100 pg/ml of fraction eluted from resins coupled with AA3 IgG loaded with partially purified DM20.

To gain further insight into the structure of the secreted PLP gene product, we studied whether the activity could be blockedby AH7-2a, a monoclonal antibody recognizing PLP 209-217 (Fig.1). Pretreatment of the enriched supernatants from PLP/DM20-producingNIH3T3 cells with AH7-2a monoclonal antibody for 60 min beforeits addition to the cell culture had no effect on its abilityto increase the number of oligodendrocytes (data not shown), whereaspretreatment with AA3 antibody completely inhibited it (Fig. 2).This result suggests that the secreted PLP gene product containsthe C terminus of PLP/DM20 but not the epitope 209-217 of PLP.To address this issue more directly, immunoabsorption experimentswere performed. The enriched supernatant from DM20-producing cellswas incubated with protein G-Sepharose coupled with AA3 or AH7-2aantibodies. Eluted samples were collected, and their activitywas checked. The activity of the enriched supernatant from DM20-producingcells was completely absorbed by protein G-AA3 (Fig. 5, bar 5)but not by protein G-AH7-2a (Fig. 5, bar 4) or protein G-normalrat IgG (Fig. 5, bar 3). However, when 100 pg/ml partially purifiedDM20 was added to the protein G-Sepharose coupled with AA3 orAH7-2a, activity to increase the number of GalC-positive cellswas absorbed with both AA3 (Fig. 5, bar 8) and the AH7-2a-proteinG column (Fig. 5, bar 7) but not with protein G-Sepharose coupledwith normal rat IgG (Fig. 5, bar 6). These results show that AH7-2aantibody can absorb DM20, but the epitope recognized by AH7-2ais absent in the secreted form of the PLP geneproduct.

A synthetic peptide corresponding to a portion of PLP/DM20 increases the number of oligodendrocytes

To further identify and characterize the active region of PLP/DM20, we used three PLP peptides, 209-217, 215-232, and 264-276.The residues 209-217 and 264-276 (C-terminal sequence) are specificallyrecognized by AH7-2a and AA3 antibodies, respectively (Fig. 1).Only the PLP peptide 215-232 increased the number of oligodendrocytesin the mixed glial cell culture (Fig. 6A). The dose-response curveof PLP peptide (215-232) shows that this fragment had reducedactivity at high concentrations (Fig. 6B), similar to that observedfor purified PLP (Fig. 3A). The solvent used to solubilize peptideshad no effect (data not shown). Thus, it is most likely that theactive region includes residues 215-232.

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Figure 6. Ability of synthetic PLP peptides to increase the number of GalC-positive cells in the mixed glial cell culture. A, Cells were cultured in the presence of 10³ pg/ml various synthetic PLP peptides (209-217, 215-232, and 264-276) during 4 d before fixation. Positions of the peptides are indicated in Figure 1. The number of GalC-positive cells was counted. Mean value of three control disks (4.5 cells/mm²) cultured with the solvent had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05). B, Different amounts of PLP peptide (215-232, closed circles) or serine-substituted PLP peptide (215-232, closed squares) were added to the glial cell cultures as described in Materials and Methods. The number of GalC-positive cells was counted. Open circle, Negative control (cells were cultured with a solvent); open square, positive control (cells were cultured in the presence of partially purified PLP [heparin fraction (Yamaguchi et al., 1996), 200 pg/ml total protein content]). Mean value of three negative control disks (42.2 cells per disk) had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05).

During the experiment we found that PLP peptide 215-232 was very unstable at neutral pH, which was the reason we dissolvedthis peptide in 15 mM HCl. We also synthesized a peptide in whichtwo cysteine residues had been substituted to serine. This peptidewas much more stable and showed a dose-response curve similarto that of PLP peptide 215-232 (Fig. 6B).

Addition of partially purified PLP or PLP peptide to the cell cultures prepared from P2 mouse brain did not affect the number of oligodendrocytes

Both PLP and PLP peptide showed a similar bell-shaped dose-response curve (Figs. 3, 6). Hence, when the PLP gene expressionis robustly induced a few days after birth, the culture systemwe are using should eventually be saturated with the secretedPLP gene product. We have routinely used primary hemisphere cellcultures prepared from E17 mice and began treatment with the conditionedmedium after 3 d in vitro, corresponding to P1. At this pointthere is still very little PLP gene expression and no detectablePLP protein (data not shown). However, only 3 d later PLP/DM20mRNA will be abundant enough to be detected by RNA dot analysis(Okano et al., 1987). We thus cultured the cells from large hemispheresfrom E17 and P2 (4 d after E17) and asked whether the latter canrespond to the exogenously added, partially purified PLP or PLPpeptide. As shown in Figure 7, the number of GalC-positive cellsin P2 cultures did not increase with the addition of PLP or PLPpeptide. Additional experiments had shown that by the time ofaddition of exogenous PLP the cells already contained detectableamount of endogenous protein (data not shown). Thus, the biologicalactivity of secreted PLP gene product can be exerted only whenthe PLP gene expression level is very low as in an embryonic brain.

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Figure 7. Effect of PLP or PLP peptide (251-232) on the mixed glial cultures prepared from different stages of development. Glial cells prepared from E17 and P2 were cultured with purified PLP or serine-substituted PLP peptide (215-232) as described in Materials and Methods. Control (CONT) was cultured with the solvent only. Mean value of three negative control disks (171.9 cells per disk for E17 and 205.5 cells per disk for P2) had been taken as 100%. Error bars indicate SD. *Significant difference between the two groups was calculated with an unpaired one-tailed t test (p < 0.05). Bar 1, E17 + 7 DIV, solvent only; bar 2, E17 + 7 DIV, 10 pg/ml purified PLP; bar 3, E17 + 7 DIV, 100 pg/ml serine-substituted PLP peptide (215-232); bar 4, P2 + 7 DIV, solvent only; bar 5, P2 + 7 DIV, 10 pg/ml purified PLP; bar 6, P2 + 7 DIV, 100 pg/ml serine-substituted PLP peptide (215-232).

  DISCUSSION

A premyelinating function of the PLP gene product

PLP/DM20 mRNA-positive cells appear at approximately E11 in several restricted areas of the brain and then subsequently spreadthroughout the brain (Timsit et al., 1992, 1995). It is stilla matter of debate whether these cells are oligodendrocyte progenitorsand whether the spreading involves active cell migration or awave of differentiation (Gonye et al., 1994; Hardy and Friedrich,1996). One important clue to answering these questions would beto understand the function of the early expressed PLP gene product.In this study we have shown that the PLP gene product is secretedinto the medium and exerts biological effects at extremely lowconcentrations (10 pg/ml, 0.3 pM). It increases the number ofboth GalC- and GFAP-positive cells, along with an increase inBrdU incorporation by these cells (Table 1). The fact that thesecreted PLP gene product also acts on astrocytes provides a possibleexplanation for the abnormalities found in the astrocytes fromthe jimpy mutant mouse before the myelinating period (Skoff, 1976).

We do not know whether the secreted PLP gene product acts through a receptor-mediated pathway, or which cell type is directlystimulated. Before gliogenesis begins, the nervous system is composedmainly of neurons and neuroepithelial cells. Therefore, the targetof the secreted PLP gene product at the early stage of neuraldevelopment may not be glial cells but, rather, immature stemcells or neurons. Because axonal abnormalities are found in PLPmutants (Nixon, 1982), and many of the early DM20 mRNA-positivecells are found in axon-rich regions (Timsit et al., 1995), itis intriguing to consider the possibility that the secreted PLPgene product may be a signal sent from DM20-producing cells toneurons.

In a transgenic mouse unable to synthesize PLP/DM20 (because of abnormal splicing), oligodendrocytes were present in a normalnumber (Boison and Stoffel, 1994; Boison et al., 1995). Normalnumber and development of oligodendrocytes were also observedin a PLP knock-out mouse (in which a portion of the PLP gene containingthe translation initiation codon had been deleted) (Klugmann etal., 1997). It is known that compensation often occurs when anessential gene has been knocked out. Because DM20 has been shownto be part of a gene family (Kitagawa et al., 1993), another memberof the family might compensate for the lack of the PLP/DM20 fragment.One candidate is M6b, which is also produced in oligodendrocytesand has high homology with PLP in the region corresponding toPLP 215-232 (12 amino acid residues of 18 identical). In mostPLP mutants, including the jimpy mouse, oligodendrocytes degenerate.This may be caused by a "traffic jam" of mutant PLP gene products(Gow et al., 1994, 1997; Jung et al., 1996), which seem to exerta dominant effect over wild-type PLP gene products, as shown bythe introduction of the wild-type PLP transgene into the jimpymouse (Kagawa et al., 1994; Readhead et al., 1994, Schneider etal., 1995). Therefore, even if M6b were capable of functionallycompensating for the absence of secreted PLP gene product in aPLP knock-out mouse, it may not be possible in many PLP mutants,potentially explaining the difference between the PLP knock-outmouse and mutants. We are currently studying the effect of M6bpeptide on glialcells.

An important feature of this factor is that it loses biological activity at a high concentration (Fig. 3A) and does not affectthe number of GalC-positive cells after the major induction ofthe PLP gene (Fig. 7). Because the expression level found in embryonicversus myelinating brain is so different, this self-shutting downmay be necessary for normal development of the CNS. Otherwiseoligodendrocytes will continuously increase innumber.

Possible structure of the secreted PLP gene product

Anti-PDGF and anti-bFGF antibodies were unable to suppress the activity in the enriched supernatants from PLP/DM20-producingNIH3T3 cells (Nakao et al., 1995). In contrast, the activity inthe supernatants was clearly inhibited by AA3 (recognizing PLPresidues 264-276) antibody (Fig. 2), whereas AH7-2a (recognizingPLP residues 209-217) antibody had no effect (Fig. 5). Thus, thePLP gene product secreted into the medium is not the whole moleculebut a fragment containing the C-terminal region of PLP/DM20 (althoughboth PLP and DM20 exhibit a similar activity) (Figs. 3, 5). Additionof PLP 215-232 increased the number of oligodendrocytes in mixedglial cell culture (Figs. 6, 7), and thus the active site of thesecreted PLP fragment should lie within this portion of PLP/DM20.The secreted fragment should contain at least 60 amino acids betweenresidues 215 and 264-276 (the C terminus of PLP/DM20 recognizedby antibody AA3). Position of the secreted fragment is indicatedin Figure 1 by a square.

There are several indications that correct folding of PLP/DM20 may not be necessary for its function in oligodendrocyte proliferation.First, both PLP and DM20, when solubilized by the aid of detergent,increased the number of oligodendrocytes (Figs. 3, 5). Second,a proteolipid mixture, containing PLP and DM20, isolated fromthe brain by organic solvents exhibited a similar activity (datanot shown). Third, synthetic peptide corresponding to residues215-232 of the PLP could reproduce the effect of the whole PLPor its C terminus (Fig. 6); substitution of the two cysteine residuesby serines did not disrupt the peptide activity (Fig. 6B).

Direct biochemical analysis of the secreted PLP gene product to determine its structure would be desirable. However, we havebeen unsuccessful in detecting a PLP/DM20 fragment in the supernatantafter radiolabeling PLP/DM20-producing cells and immunoprecepitationwith the AA3 antibody (Nakao et al., 1995). Thus, the fragmentof PLP/DM20 present in supernatants apparently exerts its activityat an extremely low concentration, consistent with the observationthat purified PLP at 10 pg/ml (0.3 pM) gave a maximum increasein the number of GalC-positivecells.

Factors contained in the B104 conditioned medium

Hunter and Bottenstein (1989, 1991) previously reported that the B104 conditioned medium promotes growth of O-2A progenitorsand subsequent increase in differentiated progeny. However, theB104 conditioned medium has not been fully characterized biochemically(Hunter and Bottenstein, 1991). Recently it was shown that theB104 cells produce and secrete PDGF-AA homodimer and transforminggrowth factor (TGF)- $beta$ 1 and - $beta$ 2, but the combination of PDGF andTGF- $beta$ was not equivalent to the effect of B104 conditioned medium(Asakura et al., 1997), suggesting the presence of an unidentifiedfactor. Because we have shown that the B104 cell line producesmRNA for DM20 (Ikenaka et al., 1992), and the biological activityof the B104 supernatant can be blocked by the addition of theAA3 antibody, one of the active components might be a secretedPLP geneproduct.

The number of oligodendrocytes was markedly increased with addition of B104 or G26 supernatant (up to sixfold), and this effectwas also repressed by the addition of the AA3 antibody (Fig. 4).Neither purified PLP nor PLP peptide (215-232) by itself can increasethe number of oligodendrocyte more than twofold to threefold.Thus, it is likely that the secreted PLP gene product coordinateswith other factors to regulategliogenesis.

Analysis of PLP mutant animals and humans (Pelizaeus Merzbacher disease) revealed many abnormalities that cannot be explainedsimply by the degeneration of oligodendrocytes, which are thepredominant, if not the only, cell type expressing the PLP gene.Our finding that the PLP gene product can be secreted and exertsbiological activity at an extremely low concentration suggestsa need to reconsider the pathology of the PLP mutants. It shouldalso lead to a further understanding of the mechanisms governingglialdevelopment.

  FOOTNOTES

Received Sept. 21, 1998; revised Dec. 31, 1998; accepted Jan. 8, 1999.

This work was supported by Grant in Aid 07279107 for Scientific Research on Priority Areas on "Functional Development of NeuralCircuits" and Grant in Aid 07458207 from the Ministry of Education,Science, Sports, and Culture of Japan, by a grant from the NationalCenter for Nervous, Mental, and Muscular Disorders of the Ministryof Health and Welfare of Japan, and by a grant from the NissanScience Foundation. We thank Dr. Steve Pfeiffer for the giftsof antibodies and for critical reading of this manuscript. Weare also grateful to Drs. Tetsushi Kagawa and Hiroko Baba forvaluablediscussion.
Correspondence should be addressed to Dr. Kazuhiro Ikenaka, National Institute for Physiological Sciences, Okazaki NationalResearch Institutes, 38 Aza-nishigonaka, Myodaiji-cho, Okazaki,Aichi 444-8585,Japan.

  REFERENCES

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Abstract
Introduction
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Copyright © 1999 Society for Neuroscience 0270-6474/99/1962143-09$05.00/0

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