J Biol Chem, Vol. 274, Issue 42, 29921-29926, October 15, 1999
Oligodendrocyte Programmed Cell Death and Central Myelination
Deficiency Induced in Transgenic Mice by Synergism between
c-Myc and Oct-6*
Niels A.
Jensen
§,
Mark J.
West¶, and
Julio E.
Celis
From the Departments of Medical Biochemistry and
¶ Neurobiology, University of Aarhus,
DK-8000 Aarhus C, Denmark
 |
ABSTRACT |
The basic helix-loop-helix transcription factor
c-Myc is a potent trigger of programmed cell death when overexpressed
during late oligodendrocyte development in transgenic mice. Here we
provide evidence that c-Myc can act synergistically with the Pit, Oct, Unc homeodomain transcription factor Oct-6 to produce myelin disease pathogenesis in transgenic mice. More than 70% of
c-myc/Oct-6 bitransgenic mice, obtained from crosses
between phenotypically normal heterozygous mice of various My (c-Myc)
and Oc (Oct-6) transgenic strains that express
c-myc and oct-6 transgenes under transcriptional control of the myelin basic protein gene, developed severe neurological disturbances characterized by action tremors, recurrent seizures, and premature death. Affected bitransgenic mice
exhibited multiple hypomyelinated lesions in the white matter that did
not stain with myelin-specific antibodies against myelin basic protein,
proteolipid protein, CNPase, and myelin-associated glycoprotein. The
mice also exhibited a larger number of terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end-labeling positive cells in the white matter as well as ultrastructural evidence
of glial cell death and astrogliosis. These observations indicate that
the myelin lesions observed in the c-myc/oct-6
bitransgenic mice result from the untimely programmed cell death of
oligodendroglia and that the c-myc and oct-6
transgenes act synergistically in producing the lesions.
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INTRODUCTION |
Myelin surrounds the axons of many of the nerve cells in the
mammalian nervous system and is essential for the saltatory conduction of nerve impulses (1, 2). In the central nervous system (CNS),1 a single
oligodendrocyte can form myelin internodes on between 1 and 30 different axons depending on their location within the CNS (3). The
structure of myelin is determined by a number of proteins that are
expressed specifically within the myelin-forming cells. The myelin
basic protein (MBP) gene, for example, is essential for the compaction
of the cytoplasmic membrane surfaces of myelin within the CNS (4).
Myelin internodes degenerate in portions of the white matter
(disseminated plaques) of patients with the acquired myelin disorder
multiple sclerosis. The clinical manifestations of disruptions of this
type are complex in that they often simultaneously involve the optic
nerves, the corticospinal tract, the cerebellar pathways, the brain
stem, the occulomotor pathways, the subcortical white matter, and the
dorsal columns of the spinal cord. There is now much evidence to
suggest that multiple sclerosis is an autoimmune disorder (5) and that
the molecular pathogenesis that results in the destruction of myelin in
this disease involves the FAS/APO-1/CD95 cell death pathway (6-10).
The FAS cell death pathway involves the activation of FADD, which leads
to the activation of a caspase protease cascade and ultimately to the
death of the affected cells (11, 12). There is increasing evidence that the helix-loop-helix transcription factor c-Myc plays a role in sensitizing cells to FAS-mediated programmed cell death (PCD) and that
c-Myc-mediated PCD can be prevented by caspase inhibitors (13-18).
Previously, we developed a transgenic mouse model to study the
physiological consequences of overexpressing c-myc in
oligodendroglia in the intact CNS (19, 20). In this transgenic model,
expression of a human c-myc transgene was under
transcriptional control of the MBP gene. Affected MBP/c-myc
transgenic mice developed neurological disturbances, which coincided
with an increased rate of untimely oligodendrocyte PCD. To identify
genes that potentiate c-myc-mediated PCD of oligodendroglia,
we have subsequently investigated the possibility that c-myc
acts synergistically with the Pit, Oct, Unc (POU) homeodomain
transcription factor Oct-6/SCIP/Tst-1 (21-23) in the pathogenesis of
oligodendrocyte PCD. This POU transcription factor is transiently
expressed in the promyelin cells of both oligodendrocyte and Schwann
cell lineages (24, 25). Although Oct-6 is expressed transiently in
promyelin oligodendrocytes, absence of the POU factor does not affect
myelination in the rodent CNS (26, 27), presumably because
oligodendroglia express Oct-6-related POU factors (28). We have
previously shown that transgenic mice overexpressing Oct-6 under
transcriptional control of the MBP gene develop a nonapoptotic
structural myelin abnormality, indicating that developmental regulation
of Oct-6 expression is involved in the normal assembly of myelin in the
CNS (29). In this study, we show that the majority of
c-myc/oct-6 bitransgenic mice, obtained from
crossing unaffected heterozygous mbp/c-myc and
mbp/oct-6 transgenic animals, develop severe
neurological disturbances, which coincide with the presence of multiple
hypomyelinated lesions in the white matter as well as with an increased
number of apoptotic cells in the brain. These findings indicate that
c-Myc and Oct-6 transcription factors act synergistically in the intact
CNS to trigger PCD in oligodendroglia.
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EXPERIMENTAL PROCEDURES |
Transgenic Animals, DNA Blotting, RNA Blotting, and PCR
Analyses--
The generation and the characterization of the
transgenic strains used in this study, My5, My23, Oc215, and Oc216,
have been described in detail elsewhere (20, 29). Transgenic mice were identified by slot blots, Southern blots, and PCR of DNA samples taken
from the tail. For PCR analysis, the following program was used in the
thermocycler: one cycle at 96 °C for 5 min; 30 cycles each at
96 °C for 30 s, 55 °C for 30 s, and 74 °C for 3 min;
and one cycle at 74 °C for 8 min. The following primers were used: MBP promoter primer, sense: 5'-GGG CCC CGC GCG TAA CTG TGC G-3'; Oct-6
primer, antisense: 5'-CCT CCG CCT ACC CAA CAC CAC G-3'; and
c-myc primer, antisense: 5'-CCT CCG CCT ACC CAA CAC CAC
G-3'. Primers for the mouse immunophilin gene muFKBP38 (30) were used as positive controls for the genomic DNA template (sense: 5'-CGG ATG
AAG ACA CTG GTC-3' and antisense: 5'-CAT GAG CGG GAC ACT GAG-3'). For
Northern blotting, total brain RNA was extracted by the isothiocyanate method (31), electrophoresed in formaldehyde-agarose gels, blotted onto
Hybond N (Amersham Pharmacia Biotech) membranes, and hybridized with
32P-labeled megaprime (Amersham Pharmacia Biotech) probes.
DNA Nick End Labeling by the TUNEL Method--
Mice were
perfused intracardially with 1% paraformaldehyde. The brains were
removed, embedded in OCT compound (Tissue Tek), and frozen with
CO2 gas. Sections (10 µm) were cut with a cryostat microtome and collected on glass slides. The TUNEL method (32) was used
to detect cells with fragmented DNA. Tissue sections were air-dried and
incubated with 3% H2O2 for 5 min at room
temperature to inactivate endogenous peroxidase. The sections were
rinsed three times in Hanks' buffer followed by a single rinse in
terminal deoxynucleotidyltransferase buffer (0.5 M
cacodylate, pH 6.8, 1 mM CoCl2, 0.5 mM dithiothreitol, 0.05% bovine serum albumin, 0.15 M NaCl) and then incubated for 1 h at 37 °C in a
moist chamber with 40 µM biotin-16-dUTP (Roche Molecular
Biochemicals) and 0.5 U terminal deoxynucleotidyltransferase/µl
(Roche Molecular Biochemicals) in terminal deoxynucleotidyltransferase
buffer. After three to five washes in Hanks' buffer, the sections were
incubated for 1 h at 37 °C in Vectastain elite ABC peroxidase
standard solution (Vector Laboratories), rinsed twice in Hanks'
buffer, and stained for 10-15 min at room temperature using the
aminoethylcarbazole substrate kit for horseradish peroxidase (Vector
Laboratories). The sections were counterstained with Mayer's
hematoxylin and mounted with Aqua-Poly/Mount (Polysciences, Inc.).
Electron Microscopy--
The animals were deeply anesthetized
with pentobarbital and transcardially perfused with a
phosphate-buffered solution of 1% glutaraldehyde and 1%
paraformaldehyde (pH 7.2). The perfused animals were immersed in the
same fixative for 2-7 days. Tissue samples were postfixed in 1%
osmium, dehydrated, and embedded in Epon. Ultrathin sections were
mounted on mesh grids and stained with uranyl acetate and lead citrate.
Immunohistochemistry--
For immunohistochemistry, the brains
and optic nerves were removed from transgenic and control mice and
immediately frozen in N2. Tissue sections (10 µm) were
cut with a cryostat microtome, collected on glass slides, and fixed
with methanol. The sections were incubated with neurofilament
(undiluted culture supernatant), myelin-associated glycoprotein (Roche
Molecular Biochemicals) (diluted 1:10 in Hanks' buffer), CNPase (Roche
Molecular Biochemicals) (diluted 1:100 in Hanks' buffer), and MBP
(Biogenesis) (diluted 1:100 in Hanks' buffer) antisera for 1 h at
37 °C in a moist chamber. Following several washes in Hanks'
buffer, the sections were incubated with appropriate secondary
rhodamine-conjugated antisera (Dako, Denmark) (diluted 1:50 in Hanks'
buffer) for 30 min at 37 °C in a moist chamber. The sections were
extensively washed in Hanks' buffer, mounted, and visualized with a
Leica DMRB fluorescent microscope. Photographs were taken with a
rhodamine filter.
Two-dimensional Gel Electrophoresis and Western
Immunoblotting--
Two-dimensional gel electrophoresis (15%
acrylamide gels; isoelectric focusing, nonequilibrium pH gradient
electrophoresis), and two-dimensional immunoblots were carried out as
described previously (33, 34). Two-dimensional gel Western blots were prepared from two-dimensional gels of total brain proteins. The blots
were blocked overnight with 1% (w/v) Difco skimmed milk (dehydrated)
in Tris-buffered saline and followed by a 2-h incubation with CNPase
(Roche Molecular Biochemicals) mouse monoclonal antiserum (1:1000
dilution). The immunoreactive proteins were visualized with the
enhanced chemiluminiscence (ECL) kit from Amersham Pharmacia Biotech.
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RESULTS |
c-Myc and Oct-6 Transgenic Mice--
For a previous series of
studies designed to investigate the pathological consequences of
overexpression of either c-Myc or Oct-6 proteins during late
oligodendrocyte development, we generated strains of
mbp/c-myc transgenic mice, designated My (20),
and strains of mbp/oct-6 transgenic mice,
designated Oc (29), in which c-myc and oct-6
transgenes, respectively, are expressed under transcriptional control
of the mbp gene. Backcrossing transgenic mice from the
c-Myc strains, My5 and My23, and the Oct-6 strains, Oc215 and
Oc216, with nontransgenic animals of the same genetic background
resulted in offspring with no neurological disturbances (Table
I). Only homozygous mice from strains My5
and Oc215, which comprised about 25% of the offspring from
heterozygous crosses (Table I), developed neurological disturbances.
These included the development of severe action tremors around
postnatal day 10, recurrent seizures, and premature death during the
third to fifth postnatal weeks. A lower incidence of neurological
disturbances was observed in homozygous mice of the My23 strain, in
that only about 13% of the mice derived from heterozygous matings were
affected. There was no evidence of disease in either heterozygous or
homozygous mice from the Oc216 strain.
c-Myc/Oct-6 Bitransgenic Mice--
To investigate the possibility
of a synergism between c-Myc and Oct-6 in the pathogenesis of
myelin disease in the intact CNS, heterozygous mice from various My and
Oc strains were crossed to generate c-Myc/Oct-6 bitransgenic mice
(Fig. 1B). In contrast to the
effects observed when My and Oc transgenic mice are backcrossed with
nontransgenic controls, most of the bitransgenic animals developed
neurological disturbances similar to those observed in the homozygous
My and Oc mice described above (Table
II). Intermatings between My5 and Oc215
heterozygous mice produced offspring with distinct transgene genotypes
(Table II). Approximately 80% of bitransgenic mice that contained both
the mbp/c-myc and the
mbp/oct-6 transgenes developed neurological
disturbances, whereas single mbp/c-myc and
mbp/oct-6 transgenic animals were unaffected. A similar high incidence of neurological disease among c-Myc/Oct-6 bitransgenic mice derived from crosses between unaffected heterozygous My5 and Oc216 parents as well as from crosses between unaffected heterozygous My23 and Oc215 parent animals was also observed (Table II). Notably, c-Myc/Oct-6 bitransgenic mice from My5 and Oc216 crosses developed disturbances that were comparable in severity to
those observed in bitransgenics of My5 and Oc215 crosses, despite the
fact that no neurologic deficits were observed in the homozygous Oc216
mice. In addition, although a high proportion of bitransgenic offspring
of My23 and Oc215 crosses developed neurological disease, the
disturbances were generally less severe than those observed in
My5/Oc215 and My5/Oc216 bitransgenics (Table II). In contrast to the
offspring of intermatings between My and Oc transgenic strains,
neurological disturbances were not observed in either single or
bitransgenic progeny obtained from matings between heterozygous My5
mice and transgenic mice expressing an prothymosin 
, a gene up-regulated by c-Myc (35), transgene under transcriptional control of the mbp
gene.2
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Fig. 1.
Schematic diagram of transgenic
constructs. The mbp/oct-6 transgene contains
a murine MBP promoter (striped box) flanked at the 3'-end by
a full-length Oct-6 cDNA (black boxes) and splice
polyadenylation signals from the SV40 virus early region
(stippled box). The mbp/c-myc
transgene contains exons 2 and 3 (white boxes) of the human
c-myc gene flanked at the 5'-end by the mouse MBP promoter
(striped box). The transcription start sites in the MBP
promoters are indicated by arrows. The amplified MBP/Oct-6-
and MBP/c-Myc-specific PCR fragments shown in B are
indicated by black lines. The POU-specific domain
(PSD) and the POU homeodomain (PHD) in the
oct-6 gene are indicated by white boxes.
kb, kilobase(s). B, genotyping of transgenic mice
by PCR. DNA obtained from tail biopsies were subjected to PCR analysis
as described under "Experimental Procedures." The primer pairs used
to detect the mbp/oct-6 and the
mbp/c-myc transgenes produce bands of 394 bp
(designated oct-6) and 362 bp (designated c-myc),
respectively. The positive control primer set for the DNA template
produces a single band of 280 bp (designated control). Each lane
represents PCR reactions with the same template DNA and is used to
characterize each mouse as either single or bitransgenic. The three
major bands in the DNA ladder are 2642 bp, 1000 bp, and 500 bp,
respectively.
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Table II
Synergistic effect of Oct-6 and c-Myc in disease progression
Mice derived from intermatings between c-Myc and Oct-6 transgenic
lines were followed closely for the development of neurologic deficits
and genotyped by PCR and by Southern blotting using DNA purified from
tail biopsies.
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Characterization of c-Myc/Oct-6 Bitransgenic Mice--
The
behaviorally affected c-Myc/Oct-6 bitransgenic mice exhibited
multiple lesions in white matter regions that did not stain with
antibodies against the myelin-specific proteins CNPase,
myelin-associated glycoprotein, and MBP (Fig.
2, D, F, and
H). These lesions appear to be primary myelin lesions in
that no difference was observed in the expression of neurofilaments in
axons of the white matter of c-Myc/Oct-6 transgenics and controls
(Fig. 2, A and B). Consistent with the
immunohistochemical staining pattern described above, CNPase
two-dimensional Western blots indicated that the levels of CNPase in
affected My/Oc animals was notably lower than those of affected My and
Oc mice (Fig. 3). Ultrastructural
analyses were carried out on selected regions of the central nervous
system of c-Myc/Oct-6 bitransgenic mice. Fig.
4, A-C shows the
ultrastructural features of lesions in the optic nerves of an affected
c-Myc/Oct-6 bitransgenic mouse. As shown in the low power image in
Fig. 4A, the axons in the lesion were unmyelinated and there
was a pronounced astrogliosis. In addition, degenerating glial cells
with pyknotic nuclear chromatin (Fig. 4B) and abnormal
myelin profiles (Fig. 4C) were occasionally observed in the
lesions. The affected c-Myc/Oct-6 bitransgenic mice also exhibited
a pronounced decline in the levels of expression of both MBP and
proteolipid protein mRNAs in the brain. These levels were
comparable to those observed in age-matched affected homozygous My5
transgenic mice (Fig. 4D). Four to five times more TUNEL
positive nuclei were observed in the brains of bitransgenic animals
than in age-matched controls (Fig. 4E). Taken together,
these results suggest that the myelin disorder observed in bitransgenic
animals resulted from the untimely PCD of myelin-forming oligodendroglia.
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Fig. 2.
Immunohistochemical localization of
neurofilament, CNP, myelin-associated
glycoprotein, and MBP in the cerebellum of c-Myc/Oct-6 transgenic
mice and controls. Micrographs of saggital sections through the
cerebellum of a nontransgenic control (A, C,
E, and G) and an affected c-Myc/Oct-6
(B, D, F, and H) transgenic
mouse at P24. Note the similar distribution of neurofilament
(NF) immunoreactivity in the control and the bitransgenic
mouse and the blotchy appearance (arrows) of CNPase
(D), myelin-associated glycoprotein (MAG)
(F) and MBP (H) immunoreactivity in the white
matter (w) of the c-Myc/Oct-6 (D, F,
and H) transgenics.
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Fig. 3.
Two-dimensional Western blots of brain
proteins. Left panels, two-dimensional Western blots
obtained by nonequilibrium pH gradient electrophoresis
(NEPHGE) of brain proteins of a nontransgenic control mouse
(A) and affected c-myc (C),
c-myc/Oct-6 (E), and Oct-6 (G)
transgenic mice at post natal day 20. The blots were reacted with a
polyclonal anti-CNP antibody and developed (for 15 s) with the ECL
procedure. Arrows indicate various CNP isoforms. Note the
reduction in the amounts of all isoforms of CNPases in the bitransgenic
animal (C). Right panels, Coomassie-stained
two-dimensional (NEPHGE) gels of nontransgenic control
(B) and affected c-Myc (D), c-Myc/Oct-6
(F), and Oct-6 (H) transgenic mice indicate the
relative amount of brain proteins loaded/gel. Note that the relative
amounts of proteins analyzed are the same for all four mice.
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Fig. 4.
Molecular pathological characterization of
the disease phenotype. Electron micrographs of optic nerves
(A, B, and C) from an affected
bitransgenic mouse at P20 showing pronounced hypomyelination
(A), a degenerating glial cell with pyknotic chromatin
(B), and an axon ensheathed by abnormal "serpentine"
myelin profiles (C). Scale bars, 2 µm.
D, Northern blot analysis showing markedly reduced levels of
expression of MBP and proteolipid protein (PLP) mRNAs in
c-Myc/Oct-6 bitransgenic mice. Total brain RNA from affected
c-Myc/Oct-6, Oct-6, and c-Myc transgenic mice and from
nontransgenic controls was isolated at post natal day 20 and used in
successive hybridizations with MBP, proteolipid protein, and  -actin
probes, as described. Hybridization with the -actin probe indicates
the relative amounts of total RNA (10 µg/lane). E, graphic
representation of the number of TUNEL-labeled cells observed in three
matched saggital sections approximately 1 mm from the midline, from the
brains of a control, and an affected c-Myc/Oct-6 double transgenic
mouse at post natal day 20.
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DISCUSSION |
The phenotype of the c-Myc/Oct-6 bitransgenic mice is
consistent with the hypothesis that the helix-loop-helix transcription factor c-Myc and the POU homeodomain transcription factor Oct-6 act synergistically to promote inappropriate oligodendrocyte PCD in
affected animals. Hallmarks of the disease phenotype of
c-Myc/Oct-6 bitransgenic mice include the presence of multiple
disseminated lesions of pronounced hypomyelination in the white matter,
a general decline in steady-state levels of several major myelin
proteins and their mRNAs, an increased number of TUNEL-positive
cells, and ultrastructural evidence of apoptotic glial cell death in affected areas. The rationale behind the experiments described in this
report was based on the previous finding that Oct-6 is expressed
transiently in oligodendroglial cells (24) and that the POU factor has
been shown to function synergistically in transcriptional regulation
with the large T antigen of the human papovavirus JC (36), a
gliatrophic virus responsible for the severe myelin disorder referred
to as progressive multifocal leukoencephalopathy (37, 38). POU factors
are versatile transcriptional regulators that, through the POU domain
or the N-terminal transactivation domain, establish associations
with specific coactivators present in postmitotic and proliferative
cells during development (39, 40). The POU transcription factor Oct-6
is expressed in numerous cell types during mammalian development
(21-23, 41-45) and has been implicated in various developmental
processes ranging from the regulation of cell division and
differentiation to the specification and survival of particular
neuronal subtypes (46-48). The finding of c-Myc and Oct-6
synergism in promotion of pathological oligodendrocyte PCD indicates
that the Oct-6 transcription factor potentiates the lethal attribute of
c-Myc in oligodendroglia in the intact CNS. To our knowledge, this
represents the first evidence of a synergistic relationship between
these transcription factors in a mammalian disease process.
Assuming that inappropriate expression of c-Myc interferes with
cellular regulatory proteins, the induction of pathological PCD appears
to be a multistage process similar to the development of neoplasm in
transgenic mice, in which c-Myc functions synergistically with Bcl-2
and cyclin D1 proteins to promote lymphoid tumors (49-53). c-Myc is a
short lived basic helix-loop-helix-leucine zipper transcription factor
that harbors an N-terminal transcriptional activation domain and a
C-terminal DNA-binding dimerization domain (54). c-Myc functions as a
dimer in the transcriptional regulation of target genes together with
the ubiquitously expressed basic hexix-loop-helix-leucine zipper factor
Max, and stimulation of both proliferation and apoptosis seems to
depend on the transcriptional regulating properties of c-Myc (55).
The cooperation between c-Myc and Bcl-2 in neoplastic transformation of hemopoietic cells, for example, relies on the ability
of Bcl-2 to suppress c-Myc-induced PCD without compromising the
proliferative capacity of these cells (56, 57). In addition, oncogene
cooperation between c-Myc and ras transgenes has
also been observed in the transformation of hemopoietic cells in
transgenic mice (58-60). However, the mechanism by which Ras effects
cell viability appears to be more complex in that it has recently been demonstrated that oncogenically activated Ras potentiates
c-Myc-induced apoptosis, presumably through a mechanism that
involves activation of the Raf kinase pathway (61, 62).
There is an increasing amount of evidence that c-Myc is not a
primary trigger of apoptosis itself, but rather facilitates apoptosis
induced by the FAS/CD95 pathway (16, 18, 63). Accordingly, it is
appropriate to view the destruction of oligodendrocytes in the
c-Myc/Oct-6 bitransgenic mice as a consequence of an increased vulnerability of affected cells to a preconfigured FAS/CD95 PCD pathway, which has previously been implicated as a cell death pathway
in myelin disease pathogenesis (6, 7). This view is further supported
by the observation that the myelin lesions observed here, in the
c-Myc/Oct-6 brains, exhibit a multifocal distribution similar to
that seen in the brains of multiple sclerosis patients. Microglia, the
immune and scavenger cells of the brain, monitor the health status of
cells in the brain and spinal cord (64) and have been shown previously
to play a role in phagocytosis of myelin and glial cell remnants in
affected c-Myc transgenic mice (20). Because microglia appear to
constitutively display the ligand (FasL) for the FAS/CD95 receptor (6,
9), it is possible that reactive microglia play a direct role in PCD
pathogenesis in c-Myc/Oct-6 bitransgenic animals.
Assuming that c-Myc plays a normal physiological role in
regulation of cell proliferation and apoptosis, it is not surprising that this proto-oncogene is frequently activated during oncogenesis by
a variety of mechanisms that lead to deregulated expression (54, 65).
Our finding that c-Myc induces programmed cell death in
oligodendroglia, and not neoplasms in the intact CNS (20), is
consistent with the finding that c-Myc activation rarely occurs in
oligodendrocytic brain tumors (66). Oligodendroglial tumor cells
exhibit the properties of progenitor cells in that they often express
the early oligodendroglial differentiation marker Oct-6 (67). The
lethal nature of the combined expression of c-Myc and Oct-6 suggests
that the activation of c-Myc kills oligodendrocytic tumor cells that
are expressing Oct-6. The apparent ability of Oct-6 to potentiate c-Myc
cytotoxicity in oligodendroglia raises the possibility that PCD therapy
involving the simultaneous overexpression of Oct-6 and c-Myc proteins
has potential as a therapeutic means to ablate glial tumor cells in the
CNS.
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ACKNOWLEDGEMENTS |
We thank A. M. Bønsdorf, P. Celis, K. M.
Pedersen, D. Jensen, and A. Meier for expert technical assistance.
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FOOTNOTES |
*
This work was supported by grants from the Danish Medical
Research Council, the Danish Cancer Society, the Alfred Benzon
Foundation, the NOVO-Nordisk Foundation, the Multiple Sclerosis Society
of Denmark, and the Alzheimer Research Center at John Hopkins
University Medical School.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
To whom correspondence should be addressed: Laboratory of
Experimental Molecular Genetics, Inst. of Medical Biochemistry & Genetics, The Panum Inst. 6.5, Blegdamsvej 3B, DK-2200 Copenhagen N,
Denmark. Tel.: 45 35 32 77 22; Fax: 45 35 32 77 01; E-mail: naj@
imbg.ku.dk.
2
N. A. Jensen, unpublished observation.
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ABBREVIATIONS |
The abbreviations used are:
CNS, central nervous
system;
ECL, enhanced chemiluminescence;
MBP, myelin basic protein;
PCD, programmed cell death;
PCR, polymerase chain reaction;
POU, Pit,
Oct, Unc;
TUNEL, terminal deoxynucleotidyltransferase-mediated
dUTP-biotin nick end labeling;
bp, base pair(s);
CNPase, 2',3'-cyclic
nucleotide 3'-phosphodiesterase.
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Copyright © 1999 by the American Society for Biochemistry and Molecular Biology.
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