Department of Neurosciences, Research Institute, The Cleveland Clinic Foundation, Cleveland, Ohio 44195
Previous studies have indicated that newly formed oligodendrocytes are dynamic cells whose production, survival, and differentiation depend upon axonal influences. This study has characterized the appearance and fate of newly formed oligodendrocytes in developing rat brain. Oligodendrocytes appear in predictable locations and radially extend DM-20-positive processes that cover 80-µm domains in the cortex and 40-µm domains in the corpus callosum. These premyelinating oligodendrocytes have one of two fates: they myelinate axons or degenerate. Between 7 and 21 d after birth, ~20% of premyelinating oligodendrocytes identified in the cerebral cortex were degenerating. Oligodendrocytes that ensheathed axons expressed and selectively targeted proteolipid protein to compact myelin and did not degenerate. These observations support the hypothesis that axonal influences affect oligodendrocyte survival, differentiation, and expression of proteolipid protein gene products.
Oligodendrocytes, the myelin-forming cell in the
central nervous system (CNS)1, are neuroepithelial in origin. In vitro studies have identified and
characterized a progenitor cell, termed O2A, which gives
rise to oligodendrocytes in serum-free medium or to astrocytes in serum-containing medium (Raff et al., 1983 Studies using retroviral markers (Levison and Goldman,
1993 In vitro studies have established that oligodendrocytes
are dynamic cells that can respond to a variety of external
influences. Critical to our understanding of oligodendrocyte lineage in vivo is the characterization of factors that
regulate their numbers and survival. Recent studies of optic nerve have established that axonal signals regulate oligodendrocyte production and survival (Barres and Raff,
1993 Immunocytochemical Analysis
3-, 7-, 11- 14-, 21-, and 28-d-old and adult Sprague Dawley rats were anesthetized and perfused through the heart with 4% paraformaldehyde and
0.08 M Sorensen's phosphate buffer. The brains were removed, postfixed
overnight at 4°C, and cryoprotected in 20% glycerol. Brains were frozen
and sectioned on a freezing, sliding microtome (Microm, Heidelberg, Germany) at a thickness of 30 µm. Sections were rinsed in buffer and pretreated with microwave (1 to 2 min), 10% Triton X-100, and 1% H2O2 (30 min). Sections were stained by the avidin/biotin complex procedure by
placing the sections in the following solutions: 3% normal serum for 30 min at 22°C, primary antibodies for 5 d at 4°C, biotinylated secondary antibodies (Vector Laboratories, Burlingame, CA) diluted 1:500 for 30 min
at 22°C, enzyme (HRP)-linked biotin diluted 1:1,000, and avidin diluted
1:1,000 (Vector Laboratories) in PBS for 1 h, diaminobenzidine/hydrogen
peroxide for 8 min, and 0.04% osmium tetroxide for 30 s. After the immunostaining procedure, the sections were rinsed in buffer, placed on glass
slides, and covered with 100% glycerol and coverslips. Sections were photographed with a photomicroscope (model Axiophot; Carl Zeiss, Inc.,
Thornwood, NY).
For double-labeling immunofluorescence and confocal studies, sections
were pretreated as described above and incubated in two primary antibodies for 5 d at 4°C. Fluorescence- and Texas red-conjugated secondary
antibodies (diluted 1:100) (Jackson Laboratories, West Grove, PA) were
applied for 1 h. Sections were rinsed and mounted in a Mowiol-based
(Calbiochem, San Diego, CA) mounting medium containing 0.1% paraphenylene-diamine hydrochloride. For combined nuclear chromatin and
DM-20/PLP staining, 30-µm-thick sections were immunostained by the
avidin/biotin complex procedures as described above, rinsed in buffer, and
placed in Hoechst 3325A dye (8 µg/ml in PBS) (Sigma Chemical Co., St.
Louis, MO) for 60 min. Sections were rinsed, placed on slides, and covered with glycerol and coverslips. Immunoreactivity was photographed
with bright-field optics. Hoechst 3325A staining was photographed under ultraviolet illumination.
Antibodies
Rat monoclonal antibodies directed against the 13 carboxy-terminal
amino acids of DM-20 and PLP were purchased from Agmed Inc. (Bedford, MA). Rabbit polyclonal antibodies were generated against the 35 amino acids specific for PLP protein. Western blot analysis confirmed the
specificity of the reactivity of these two reagents. Rabbit anti-rat NG2 antibody was kindly provided by Joel Levine (State University of New York
at Stony Brook) and has been described (Levine et al., 1993 Confocal Microscopy
Sections were analyzed on a confocal laser scanning microscope (model
Aristoplan; Leica, Inc., Deerfield, IL). Confocal images represent optical
sections of ~1 µm axial resolution. Single images represented an average
of 32 line scans of the chosen field. Fluorescence in red and green channels was collected simultaneously. In the red/green merged images, areas
of colocalization are yellow. Images were photographed with a focus
graphics 35-mm film recorder.
Morphometric and Statistical Analysis
The diameter or area occupied by DM-20/PLP-positive premyelinating
oligodendrocytes was measured using a microscope (model Axiophot;
Carl Zeiss, Inc.) fitted with a grid-patterned reticule and a 40× objective.
In the corpus callosum, the cells were measured perpendicular to the cell
cluster and developing axons. Measurements were converted to microns
and unpaired Student's t test was used for comparing the diameter of cells
in the cortex and corpus callosum.
Characterization of Premyelinating Oligodendrocytes in
the Cerebral Cortex and Corpus Callosum
To determine if premyelinating oligodendrocytes could be
identified with DM-20/PLP antibodies, sections of developing rat brain were immunostained with a monoclonal
antibody directed against the 13 carboxy-terminal amino
acids common to both proteins. In the cerebral cortex, myelination occurs in a predictable temporal and spatial sequence during the first three postnatal weeks. Myelination begins rostral to corpus callosum and progresses to the
pial surface. Fig. 1 A demonstrates the distribution of DM20/PLP immunoreactivity in 11-d-old rat brain. Vertically
oriented DM-20/PLP-positive, myelinated fibers extend
from the deep cortical layers toward the pial surface.
Patches of DM-20/PLP staining were also present near the
leading edge of the myelination front (Fig. 1 A, arrowheads) and in layer I of the cortex. Most brain regions containing patches of DM-20/PLP immunoreactivity at 11 d are
myelinated by 21 d (Fig. 1 B). When examined at higher
magnification, many of these patches consisted of single
cells that symmetrically radiated DM-20/PLP-positive processes (Fig. 1 C, arrowheads). Occasionally, these cells
occurred in pairs (Fig. 1 C, asterisk), and processes of these
paired cells occupied separate neuropil domains. Other
DM-20/PLP-positive cells were connected to developing
myelin internodes (Fig 1 C, arrows) and were located in
deeper layers of the cortex. Some areas of DM-20/PLP immunoreactivity were fragmented and covered neuropil areas that were similar in size to oligodendrocytes that radially extend multiple processes (Fig. 1 D, arrowheads).
These profiles represent dying oligodendrocytes, and they
are described in detail below.
Premyelinating oligodendrocytes detected in the developing corpus callosum were strikingly different from those
in the cerebral cortex. DM-20/PLP-positive cell bodies
usually occurred in clusters of two to four cells (Fig. 2, A
and B, arrowheads) that were oriented parallel to developing axons. These cells extended multiple processes that appeared to overlap extensively. At postnatal day 7, some clusters of DM-20/PLP-positive cells did not include obvious developing myelin internodes (Fig. 2 A; also see Fig. 3,
C and D), while others did (Fig. 2 B, arrows). By postnatal
day 11, the corpus callosum contained many clusters of
DM-20/PLP-positive cells and developing myelin internodes
(Fig. 2 C). Since our analysis suggested that premyelinating oligodendrocytes in the cerebral cortex had more orderly
arranged processes than those in the corpus callosum, sections stained with DM-20/PLP antibodies were analyzed
by confocal microscopy (Fig. 3). Fig. 3 A is a single confocal image (~1.0-µm-thick) of a premyelinating oligodendrocyte in the developing cerebral cortex. Fig. 3 B is a stack
of 20 confocal images (~20-µm-thick) of the same cell.
The relatively symmetrical and nonoverlapping distribution of the DM-20/PLP-positive processes is apparent in both images. When a similar comparison was performed
on a cluster of premyelinating oligodendrocytes in the developing corpus callosum (Fig. 3, C and D), their processes
arborized and overlapped extensively. Our initial immunocytochemical analysis also suggested that premyelinating oligodendrocytes occupied larger neuropil domains in
the cerebral cortex than in the corpus callosum. Therefore,
the radius of the area occupied by cell bodies and processes of individual DM-20/PLP-positive premyelinating
oligodendrocytes in P7 corpus callosum and cerebral cortex was compared. The radius of premyelinating cells was
78.5 ± 8.2 µm (n = 60) in the cortex and 39.8 ± 9.5 µm (n
= 45) in the corpus callosum. Student's t test demonstrated that this difference was statistically significant (P < 0.001).
Premyelinating Oligodendrocytes Differentiate into
Myelinating Oligodendrocytes
The distribution of DM-20/PLP immunoreactivity indicated that premyelinating oligodendrocytes differentiate
into myelinating oligodendrocytes in predictable locations
in the cerebral cortex. Fig. 4 depicts three stages in the
progression from premyelinating to myelin-forming oligodendrocyte. The premyelinating oligodendrocyte in Fig. 4 A
radially extends DM-20/PLP-positive processes that have
no obvious extensions along axons. Initial stages of myelination can be identified by the extension of T-shaped processes from the premyelinating oligodendrocytes (Fig. 4 B,
arrowheads). The top of the T's are oriented parallel to axonal bundles and represent initial stages of axonal ensheathment. Analysis of cells in more advanced stages of
myelination (Fig. 4 C) indicated that only a small percentage of the premyelinating oligodendrocyte processes ensheath axons. Fragmented DM-20/PLP-positive processes
were not detected near developing myelin internodes, suggesting that premyelinating oligodendrocyte processes that
do not ensheath axons were resorbed.
The proteolipid protein gene produces two alternatively
spliced proteins (DM-20 and PLP) that differ by 35 additional amino acids (exon 3b) in PLP. Previous studies have
indicated that DM-20 is expressed before PLP during
brain development (Macklin, 1992
Degeneration of Premyelinating Oligodendrocytes
A proportion of DM-20/PLP-positive cells, located in the
same brain regions as the premyelinating oligodendrocytes described above, had fragmented DM-20/PLP immunoreactivity. Many such cells retained the shape and size
of premyelinating oligodendrocytes, while other regions of
DM-20/PLP immunoreactivity consisted of dots that were
less orderly but distributed over an 80-µm radius. Cells
with fragmented DM-20/PLP immunoreactivity appear to
represent premyelinating oligodendrocytes that are degenerating, which is consistent with previous studies demonstrating extensive programmed cell death during early
stages of oligodendrocyte differentiation (Barres et al.,
1992
Table I.
Percentage of Dying Premyelinating Oligodendrocytes
in Developing Cerebral Cortex
). Cells
committed to the oligodendrocyte lineage in vitro can respond to a variety of growth factors, and based on morphology and molecular phenotype, they are generally grouped
into progenitors, immature oligodendrocytes (premyelinating), and mature oligodendrocytes (myelinating) (Gard
and Pfeiffer, 1990
; Hardy and Reynolds, 1991
; DuboisDalcq and Armstrong, 1992; Miller, 1996
). PDGF binds to
and stimulates the division of O2A cells in vitro (Richardson et al., 1988
; Hart et al., 1989b
), and as O2A cells differentiate into oligodendrocytes, they downregulate PDGF
R
and fail to bind or respond to PDGF (Hart et al., 1989a
). The proteoglycan, NG2, colocalizes with PDGF
R in vitro
and in vivo (Nishiyama et al., 1996a
), and these molecules
may be functionally coupled on the surface of O2A cells
(Nishiyama et al., 1996b
). PDGF
R-/NG2-positive cells
populate the brain well before myelination begins (Nishiyama et al., 1996a
), and dual-labeling studies indicate that
these cells can give rise to galactocerebroside- and myelin basic protein (MBP)-positive oligodendrocytes (Levine et
al., 1993
; Nishiyama et al., 1996a
).
) and immunocytochemical studies using glycolipid
and ganglioside antibodies (LeVine and Goldman, 1988
;
Gard and Pfeiffer, 1990
; Hardy and Reynolds, 1991
; Warrington and Pfeiffer, 1992
) have identified immature or
premyelinating oligodendrocytes in developing rodent brain.
Myelin protein antibodies have not been used to identify
premyelinating oligodendrocytes in vivo. mRNA encoding DM-20, a spliced product of the proteolipid protein (PLP)
gene, has been detected in developing brain before myelin
formation (Macklin, 1992
; Timsit et al., 1995
), and mice with
PLP gene mutations have phenotypes at stages before active myelin formation (Skoff, 1982
; Knapp et al., 1986
).
These observations suggest that DM-20 is expressed by
immature or premyelinating oligodendrocytes.
, 1994
; Barres et al., 1993
; Burne et al., 1996
) and that
as many as 50% of all newly formed oligodendrocytes die
by programmed cell death (Barres et al., 1992
). Similar to many developing neurons, newly formed oligodendrocytes
appear to compete for survival factors, and their overproduction presumably helps assure that all appropriate axons are myelinated. While our understanding of oligodendrocyte lineage in vivo is evolving, further characterization
of the appearance, fate, and molecular events that occur
during oligodendrocyte differentiation is needed. Therefore, we used antibodies directed against the myelin proteins PLP and DM-20 to characterize oligodendrocyte lineage in vivo. Our results demonstrate that DM-20-positive
premyelinating oligodendrocytes are produced in predictable locations during development and suggest that their
survival is dependent on myelination of appropriate axons.
In addition, we provide evidence that as oligodendrocytes ensheath axons, they express and selectively target PLP to
developing myelin internodes.
Materials and Methods
).
Results
Fig. 1.
Comparison of the distribution of DM-20/PLP immunoreactivity in sections from 11- (A) and 21-d-old (B) rat brain. The increased distribution of immunoreactivity in B reflects the developmental progression of myelination. Premyelinating oligodendrocytes
are concentrated at the leading edge of myelinated fibers projecting toward the pial surface (A, arrowheads) and in layer I of the cortex.
Premyelinating oligodendrocytes radially extend multiple processes that cover distinct neuropil domains (C, arrowheads). While most
premyelinating oligodendrocytes in the cerebral cortex are separated from each other, occasional pairs are detected (C, asterisk). Processes of adjacent cells rarely overlap even when cells appear in pairs. Myelinating oligodendrocytes (C, arrows) send processes to vertically oriented DM-20/PLP-positive myelin internodes. Other regions of DM-20/PLP immunoreactivity is fragmented (D, arrowheads)
and covers approximately the same neuropil area as healthy-appearing premyelinating oligodendrocytes (D, arrow). Bars: (A and B)
200 µm; (C and D) 50 µm.
[View Larger Version of this Image (124K GIF file)]
Fig. 2.
Premyelinating oligodendrocytes in the corpus callosum from 7- (A and B) and 11-d-old (C) rats. DM-20/PLP-positive premyelinating oligodendrocytes occur in clusters (A and B, arrowheads) in the corpus callosum. Clustered perikarya appear before evidence
of myelin formation (A) and persist during active myelination (B and C). Bars, 50 µm.
[View Larger Version of this Image (97K GIF file)]
Fig. 3.
Premyelinating oligodendrocytes in cerebral cortex and corpus callosum have different morphologies. Confocal images of single (A and C) and reconstructions of 20 (B and D) 1-µm-thick optical sections of DM-20/PLP-positive premyelinating oligodendrocytes from the cerebral cortex (A and B) and corpus callosum (C and D). Cortical cells (A and B) extend an orderly array of processes that
tend to branch in a Y-shaped manner as they terminate. Premyelinating oligodendrocytes in the corpus callosum (C and D) occur in
groups and extend processes in a less orderly and overlapping fashion. Bars, 10 µm.
[View Larger Version of this Image (112K GIF file)]
Fig. 4.
Premyelinating oligodendrocytes differentiate into myelinating oligodendrocytes. DM-20/PLP-positive oligodendrocytes
before myelination (A), during early stages of axonal ensheathment (B, arrowheads), and during active myelination (C). Bar, 10 µm.
[View Larger Version of this Image (56K GIF file)]
; Timsit et al., 1995
). To
determine if DM-20 and PLP could be detected at different stages of oligodendrocyte differentiation, sections were double-labeled with one antibody specific for DM20/PLP and another specific for PLP. Premyelinating and
myelinating oligodendrocytes were identified and examined by confocal microscopy. The PLP-specific antibody
did not stain premyelinating oligodendrocytes. During early stages of myelin formation (cells extending multiple
DM-20/PLP-positive processes and short DM-20/PLP-
positive developing myelin internodes), PLP was detected
in oligodendrocyte perinuclear cytoplasm and in some of
the developing internodes (Fig. 5 A). At later stages of
myelination (Fig. 5 B), all developing myelin internodes
were both DM-20/PLP and PLP positive. These observations indicate that PLP is expressed at very low levels in
premyelinating oligodendrocytes and during early stages
of axonal ensheathment and that PLP is targeted exclusively to myelin internodes. In contrast, DM-20 was detected on all surface membranes of premyelinating and
myelinating oligodendrocytes. These observations raise
the possibility that axonal influences regulate differential
expression of PLP gene products as premyelinating oligodendrocytes differentiate into myelinating oligodendrocytes.
Fig. 5.
Comparison of the distribution of DM-20/PLP (red) and PLP (green) in confocal images of oligodendrocytes. Areas of colocalization appear yellow. During early stages of axonal ensheathment, DM-20/PLP immunoreactivity is evenly distributed on oligodendrocyte processes (A, red) and developing myelin internodes (A, red and yellow), while PLP-specific immunoreactivity is restricted to
perinuclear cytoplasm and developing myelin internodes (A, yellow). In more mature oligodendrocytes, DM-20/PLP is detected in oligodendrocyte processes and myelin, while PLP is restricted to perinuclear cytoplasm and myelin (B, yellow). Asterisks and arrowheads
denote nucleus of cell and myelin internodes. Bars, 10 µm.
[View Larger Version of this Image (31K GIF file)]
). A salient morphological feature of cells undergoing
programmed cell death is fragmentation and condensation of nuclear chromatin. To determine if premyelinating oligodendrocytes with fragmented PLP/DM-20 staining also
contained fragmented nuclear chromatin, sections were
stained with DM-20/PLP antibodies and with a DNAbinding dye. Premyelinating oligodendrocytes with evenly distributed DM-20/PLP staining had diffuse and evenly
stained nuclear chromatin (Fig. 6 A), while cells with fragmented DM-20/PLP staining had fragmented and condensed nuclear chromatin (Fig. 6, B and C). At the leading
edge of myelination in the cerebral cortex, the total number of premyelinating cells was greatest at postnatal days
11 and 14 (Table I), reflecting peak periods of initial stages
of myelination. The percentage of total premyelinating cells that were degenerating was ~20% between postnatal
days 7 and 21 and was 37% at day 28 (Table I).
Fig. 6.
Comparison of DM-20/PLP immunoreactivity and nuclear chromatin staining in developing rat brain. Premyelinating oligodendrocytes with DM-20/PLP immunoreactivity evenly distributed on their surface (A) have diffuse nuclear chromatin staining (A, inset). Premyelinating oligodendrocytes with fragmented DM-20/PLP staining (B) and DM-20/PLP-positive necrotic-appearing cells (C)
have condensed and fragmented nuclear chromatin (B and C, inset). A, B, and C were photographed with bright field optics; insets were
photographed with ultraviolet optics. Bar, 10 µm.
[View Larger Version of this Image (51K GIF file)]
Origin of Premyelinating Oligodendrocytes
To investigate if DM-20/PLP-positive cells originate from
NG2-positive cells or from another cell that is committed
to the oligodendrocyte lineage, sections were double-labeled
with NG2 and DM-20/PLP antibodies and examined by
confocal microscopy. In sections from 3-d-old brain, NG2positive cells were present throughout the cerebral cortex,
but few DM-20/PLP-positive cells were detected (data not
shown). Sections from 7-d-old brain contained significant
numbers of DM-20/PLP-positive premyelinating oligodendrocytes (Fig. 7). While most cells were stained with
either NG2 or DM-20/PLP antibodies (Fig. 7 A), a small but
consistent population of cells was stained by both antibodies (Fig. 7, B and C). Cells positive for both NG2 and
DM-20/PLP were identified by weak DM-20/PLP immunoreactivity in perinuclear cytoplasm and on proximal
processes. When both channels were imaged, the intensity
of NG2 and DM-20/PLP immunoreactivity in double-labeled
cells was much weaker than that detected in surrounding
cells, which were either NG2 or DM-20/PLP positive. These observations provide additional support that NG2positive progenitor cells produce oligodendrocytes in vivo
(Levine et al., 1993; Nishiyama et al., 1996a
).
Based on the distribution of PLP and DM-20, this study
provides additional insights into the molecular and cellular
events that occur during oligodendrocyte differentiation in
vivo. Our studies confirm that a significant percentage of
newly formed oligodendrocytes degenerate and provide
the first description of their location and phenotype. Oligodendrocytes that degenerate express DM-20 and do not
ensheath axons or express detectable levels of PLP, the
major structural protein of compact myelin. These observations are consistent with the hypothesis that oligodendrocyte cell death occurs before any significant commitment to myelin formation and that axonal ensheathment is
essential for oligodendrocyte survival. Fig. 8 schematically
summarizes stages and features of oligodendrocyte differentiation in vivo and is based on differential detection of
DM-20 and PLP in confocal images. This model supports and extends those proposed previously (Hardy and Reynolds, 1991; Warrington and Pfeiffer, 1992
; Ffrench-Constant, 1992
; Barres and Raff, 1994
) and is based on direct
analysis of cells in vivo.
Oligodendrocyte Progenitors
PDGFR-, NG2-positive cells originate from discrete regions of the ventricular zone of the diencephalon (Hart et al.,
1989a
; Pringle et al., 1992
; Pringle and Richardson, 1993
;
Nishiyama et al., 1996a
). They migrate, proliferate, and
form a network of process-bearing cells that populate the
cortex before birth (Nishiyama et al., 1996a
). Each cell establishes a microdomain within the neuropil, and contact
inhibition with neighboring NG2 cells may, in part, control
their distribution. The location of cells immunostained by
both NG2 and DM-20 antibodies (Fig. 7) provides additional evidence that NG2-positive cells give rise to oligodendrocytes (Levine et al., 1993
; Nishiyama et al., 1996a
). Our studies indicate that DM-20 immunoreactivity is a reliable marker for newly formed oligodendrocytes, and the
detection of the occasional NG2/DM-20-positive cells makes
it unlikely that stages of oligodendrocyte lineage exist between NG2- and DM-20-positive cells. NG2-positive cells,
however, may represent a heterogeneous population of
cells with regard to stage and commitment to oligodendrocyte lineage, and they could have functions unrelated to
oligodendrocyte progenitors. The rate of oligodendrocyte
lineage cell differentiation can differ significantly in various brain regions. In the hindbrain, oligodendrocytes are
produced 2-3 d after the appearance of PDGF
R mRNA-
positive cells (Hardy and Friedrich, 1996
), whereas a similar transition can take several weeks in the cerebral cortex.
In addition, a distinct stage of oligodendrocyte progenitors
(04+/R-mAb
) has been described in vitro (Hardy and
Reynolds, 1991
; Bansal et al., 1992
; Gard and Pfeiffer,
1993
) and in perinatal forebrain (Pfeiffer et al., 1993
) but
was not detected in hindbrain (Hardy and Friedrich, 1996
).
Developmental and regional variations in axonal maturation and in the timing of progenitor cell generation and migration throughout the CNS may be responsible for these differences.
Differentiation of Myelinating Oligodendrocytes
Fig. 4 presents a logical progression in the differentiation
of a premyelinating to a myelinating oligodendrocyte. It
should be stressed, however, that these are images of different cells and that confirmation of this progression
awaits analysis of the development of single cells. The distribution, morphology, and molecular phenotype of premyelinating oligodendrocytes provide new insights into
mechanisms that regulate their maturation into myelinforming cells. Premyelinating oligodendrocytes radiate
processes in a symmetrical manner and establish spatial
domains within the neuropil. In the cerebral cortex, processes of neighboring premyelinating cells do not overlap
even when they appear in pairs. In the corpus callosum,
premyelinating oligodendrocytes usually occur in groups of two to four cells, their processes overlap extensively,
and each cell occupies ~50% of the neuropil domain that
cells in the cortex occupy. Since the number of myelinreceptive axons is much greater in the corpus callosum
than in the cerebral cortex, these observations support the
hypothesis that axons regulate premyelinating oligodendrocyte numbers and morphology (Barres et al., 1992,
1993; Burne et al., 1996
; Hardy and Friedrich, 1996
). The
spatial separation of premyelinating oligodendrocytes in
the cortex suggests that neighboring cells compete less for
survival factors than the clusters of premyelinating oligodendrocytes in the corpus callosum. In addition, the
symmetrical extension of premyelinating oligodendrocyte processes is consistent with the hypothesis that physical
contact with appropriate axons and/or soluble axon-derived
factors that work over short distances regulate oligodendrocyte maturation and survival. The hypothesis that axonal contact is needed for oligodendrocyte survival is also
supported by studies that demonstrated that neurons, but
not neuronal-conditioned medium, can increase the survival of oligodendrocytes maintained in vitro (Barres and Raff, 1994
).
Differentiation of oligodendrocytes parallels many aspects of polarized epithelial cell differentiation. These include dependence on cell-cell contact, expression of specific gene products, polarization of cytoskeletal networks,
development of specialized transport pathways, and formation of distinct surface membrane domains (Mostov et al.,
1992; Rodriguez-Boulan and Powell, 1992
). Although myelinating oligodendrocytes do not form the classical apical
and basolateral membrane domains or tight junctions seen
in typical epithelial cells, they do polarize their surface membranes into several biochemically and morphologically distinct domains (e.g., compact myelin, paranodal membrane,
periaxonal membranes, perikaryal surface membrane). Premyelinating oligodendrocytes can be considered as nonpolarized epithelial cells that extend processes in search of
appropriate targets. While our studies support the hypothesis that ensheathment of appropriate axons is required
for the transformation of the nonpolarized premyelinating
oligodendrocyte into a polarized myelinating oligodendrocyte, it remains to be determined if axonal contact is the
actual signal.
Our studies indicate that PLP expression and induction
of specialized transport pathways occur as oligodendrocytes polarize their surface membranes and form myelin.
The immunocytochemical studies in this report indicate
that DM-20, but not PLP, is expressed by premyelinating
oligodendrocytes. This conclusion is based on the observation that antibodies directed against epitopes shared by
DM-20 and PLP stain premyelinating oligodendrocytes,
whereas antibodies specific for PLP do not. Although this
could represent different binding affinities for the two antibodies, the PLP antibody demonstrates the same intensity and pattern of staining at 1:6,000 and 1:250 dilutions.
In addition, DM-20 has been identified as a member of an
evolutionarily conserved family of proteins that is expressed by some neurons, fish myelin, choroid plexus, and kidney tubules (Kitagawa et al., 1993; Yan et al., 1993
;
Yoshida and Colman, 1996
). In contrast, PLP evolved as a
myelin-specific protein in amphibians and has not been
identified in other tissues (Yoshida and Colman, 1996
).
Our studies raise the possibility that the 35 amino acids
specific to PLP contain signals that target PLP exclusively
to compact myelin or that prevent PLP from being targeted to nonmyelin domains.
Myelin-associated glycoprotein (MAG) and MBP antibodies also stain premyelinating oligodendrocyte cell bodies and processes (Trapp, B.D., unpublished observation).
As premyelinating oligodendrocytes differentiate into myelinating oligodendrocytes, they selectively target MAG to
the periaxonal membrane (Trapp et al., 1989), MBP to compact myelin (Sternberger et al., 1978
), and MBP mRNA
along the myelin internode (Colman et al., 1982
; Trapp et
al., 1987
). Myelinating oligodendrocytes, therefore, develop specialized transport pathways that are not present in
premyelinating oligodendrocytes. As described in myelinating Schwann cells (Kidd et al., 1996
), axons may induce
specialized microtubule networks in myelinating oligodendrocytes that target myelin-specific gene products to distinct regions of the myelin internode. Alternatively spliced forms of the MAG and MBP gene are also produced, and
select forms (L-MAG and exon 2-containing MBPs) predominate during the earliest stages of CNS development
(Quarles et al., 1973
; Barbarese et al., 1978
). Differential
expression of myelin protein isoforms may be regulated
during oligodendrocyte differentiation by alternative splicing, mRNA stabilization, or translational control.
Death of Premyelinating Oligodendrocytes
Programmed cell death is essential to the development of
many organ systems and assures appropriate cell numbers
and/or appropriate cell-cell contact (Raff et al., 1993).
Previous studies that correlated in vivo and in vitro analyses of oligodendrocyte lineage cells estimated that as many
as 50% of newly generated oligodendrocytes in the optic
nerve undergo programmed cell death (Barres et al., 1992
).
Our results established that ~20% of premyelinating oligodendrocytes in sections of the developing cerebral cortex (7-21 d) are degenerating. If oligodendrocyte survival
depends upon the availability of myelin-receptive axons,
the rate of premyelinating oligodendrocyte death may differ in white matter tracts and cerebral cortex. The incidence of premyelinating oligodendrocyte death in the cerebral cortex or optic nerve cannot be established until the
life span of premyelinating oligodendrocytes and the clearance time for degenerating oligodendrocytes are determined.
We did not detect degenerating oligodendrocyte progenitors (NG2+ cells) nor significant numbers of degenerating
myelin internodes (PLP-positive). However, hemopoietic
and microglia cells with condensed nuclear chromatin
were detected in both white and gray matter (Trapp, B.D.,
unpublished observation). Premyelinating oligodendrocytes
were not detected in brain areas after they were myelinated. These observations do not support estimates of a
constant rate of oligodendrocyte production and death in
rodent optic nerve during the first six postnatal weeks
(Barres et al., 1992; Raff et al., 1993
) and emphasize the
need for phenotyping dying cells identified by nuclear
chromatin fragmentation.
This report used PLP/DM-20-specific antibodies to describe several aspects of oligodendrocyte differentiation in vivo. Characterization of oligodendrocyte lineage cells after experimental manipulation of the developing CNS should elucidate the molecular events responsible for production, survival, and maturation of myelin-forming cells and identify potential targets for therapeutic intervention in demyelinating diseases.
Received for publication 18 September 1996 and in revised form 19 December 1996.
Address all correspondence to Dr. Bruce D. Trapp, Department of Neurosciences-NC30, The Cleveland Clinic Foundation, 9500 Euclid Avenue, Cleveland, OH 44195. Tel: (216) 444-7177. Fax: (216) 444-7927.We thank Dr. Joel Levine for NG2 antibodies, Dr. Judy Drazba for help in confocal analysis, and Lois Becker for typing the manuscript.
This work was supported by grants from the National Institutes of Health (NS-29818 to B.D. Trapp, NS-25304 to W. Macklin) and the National Multiple Sclerosis Society (NMSS RG1901 to W. Macklin).
CNS, central nervous system; MAG, myelin-associated glycoprotein; MBP, myelin basic protein; PLP, proteolipid protein.