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The Journal of Neuroscience, January 15, 1999, 19(2):759-774
Identification and Characterization of Early Glial Progenitors
Using a Transgenic Selection Strategy
Karen J.
Chandross1,
Rick I.
Cohen1,
Peter
Paras Jr1,
Michel
Gravel2,
Peter E.
Braun2, and
Lynn D.
Hudson1
1 National Institutes of Health, National Institute for
Neurological Disorders and Stroke, Laboratory of Developmental
Neurogenetics, Bethesda, Maryland 20892, and 2 McGill
University, Department of Biochemistry, Montreal, Quebec H3G1Y6,
Canada
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ABSTRACT |
To define the spatiotemporal development of and simultaneously
select for oligodendrocytes (OLs) and Schwann cells (SCs), transgenic
mice were generated that expressed a bacterial  -galactosidase (-gal) and neomycin phosphotransferase fusion protein (geo) under
the control of murine 2'3'-cyclic nucleotide 3'-phosphodiesterase (muCNP) promoters I and II. Transgenic -gal activity was detected at
embryonic day 12.5 in the ventral region of the rhombencephalon and
spinal cord and in the neural crest. When cells from the
rhombencephalon were cultured in the presence of G418, surviving cells
differentiated into OLs, indicating that during development this brain
region provides one source of OL progenitors. Postnatally, robust
-gal activity was localized to OLs throughout the brain and was
absent from astrocytes, neurons, and microglia or monocytes. In the
sciatic nerve -gal activity was localized exclusively to SCs.
Cultures from postnatal day 10 brain or sciatic nerve were grown in the presence of G418, and within 8-9 d exposure to antibiotic, 99% of all
surviving cells were -gal-positive OLs or SCs. These studies demonstrate that the muCNP-geo transgenic mice are useful for identifying OLs and SCs beginning at early stages of the glial cell
lineage and throughout their development. This novel approach definitively establishes that the -gal-positive cells identified in vivo are glial progenitors, as defined by their
ability to survive antibiotic selection and differentiate into OLs or
SCs in vitro. Moreover, this experimental paradigm
facilitates the rapid and efficient selection of pure populations of
mouse OLs and SCs and further underscores the use of cell-specific
promoters in the purification of distinct cell types.
Key words:
2',3'-cyclic nucleotide 3'-phosphodiesterase; -galactosidase; CNS; development; glia; neomycin resistance; peripheral nervous system; selection; tissue culture
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INTRODUCTION |
Many properties of neural cells have
been determined by in vitro characterization. The advantage
of a tissue culture system is that specific biological questions can be
addressed under controlled conditions. Cells derived from the
peripheral nervous system (PNS) or CNS and maintained in culture
have been shown to be physiologically, antigenically, and
morphologically similar to their in situ correlates (Landis,
1976 ; Patterson and Chun, 1977; Abney et al., 1983; Porter et al.,
1986; Barres et al., 1988; Morrissey et al., 1991) and can function
normally once transplanted back into their appropriate in
vivo environments (Porter et al., 1986; Feltri et al., 1992; Gage
et al., 1995; Gross et al., 1996; Martin et al., 1996; Li and Raisman,
1997; Lundberg et al., 1997; McKay, 1997; Svendsen et al., 1997).
Tissue culture paradigms are useful for analyzing the origins of
specific neural cell types and determining whether cells identified as
presumptive precursor cells in vivo are capable of
differentiating into mature neurons or glia. For example, in the
oligodendrocyte (OL) lineage, cells that originate from specific CNS
regions and express 2'3'-cyclic nucleotide 3'-phosphodiesterase (CNP),
PDGF- receptor, or DM-20 mRNAs are thought to represent OL
progenitors (Pringle and Richardson, 1993; Yu et al., 1994; Timsit et al., 1995; for review, see Miller, 1996). However, in view of the plasticity of neural cells and the possibility they may
transiently express some markers without committing to a specific lineage, it is difficult to determine whether these same cells differentiate into OLs or Schwann cells (SCs), making an approach for
selecting progenitors desirable.
None of the presently available selection strategies incorporate the
advantage of simultaneously marking cells for future analyses,
beginning early in their lineage progression. Using a transgenic (Tg)
model, we describe a novel method to identify mouse OL and SC
progenitors and to efficiently isolate these cells directly from the
CNS and PNS, respectively. The murine CNP (muCNP) promoters I and II
(Kurihara et al., 1990; Gravel et al., 1998) were used to drive the
expression of a -galactosidase (-gal) and neomycin
phosphotransferase (NPT, neomycin resistance) fusion gene (geo;
Friedrich and Soriano, 1991) in Tg mice (muCNP-geo).
Consistent with the expression patterns of several myelin genes (Zeller
et al., 1985; Monge et al., 1986; Jordan et al., 1989; Yu et al., 1994;
Timsit et al., 1995; Hajihosseini et al., 1996; Landry et al., 1997;
Lee et al., 1997; Parmantier et al., 1997; Peyron et al., 1997), CNP is
present in the nervous system early in mammalian development, and
increased expression coincides with the onset of myelination (Braun et
al., 1988; Reynolds and Wilkin, 1988; Jordan et al., 1989; Kanfer et
al., 1989; Sprinkle, 1989; Hardy and Reynolds, 1991; Scherer et al.,
1994; Yu et al., 1994; Peyron et al., 1997). The muCNP promoter region
was chosen to generate Tg mice because CNP expression is localized to
cells of the OL and SC lineage in the brain and peripheral nerve,
respectively, thus providing a system for analyzing and further
manipulating purified myelin-forming cells at various stages of
development. We demonstrate that the muCNP-geo transgene was useful
for identifying and characterizing OL and SC progenitors beginning
early in their lineage and for selecting viable OLs and SCs from Tg
mouse tissues.
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MATERIALS AND METHODS |
Construction of the muCNP-geo transgene and microinjection of
fertilized eggs
All animal procedures were performed according to National
Institutes of Health (Bethesda, MD) guidelines. The muCNP-geo plasmid was constructed by ligating a 3.7 kb
NotI-HindIII fragment containing muCNP-promoters
I and II (Gravel et al., 1998), to the
NotI-HindIII site of the bacterial -gal and
NPT fusion gene in a KS plasmid (pBKSgeo), a 4.2 kb reporter gene
encoding a protein with both -gal and NPT activity (a generous gift
from Dr. Philippe Soriano; Fred Hutchinson Cancer Research Center, Seattle, WA; Friedrich and Soriano, 1991). An 8 kb muCNP-geo fragment (Fig. 1) was excised with SalI and NotI,
purified from the prokaryotic portion of the plasmid by a 10-40%
(w/v) sucrose gradient, and dialyzed against injection buffer (10 mM Tris-HCl, pH 7.4, 0.1 mM EDTA). Transgenic
mice on a [C57BL/6J × C3H] F1 × [C57BL/6J × C3H]
F1 background were generated by pronucleus injection of the DNA (2 µg/ml) according to standard protocols (Hogan et al., 1986).
Tg founders were bred with either C57BL/6J or [C57BL/6J × C3H]
F1 mice, and lines were expanded by mating siblings within each
individual line. Three different lines, cgeo1-cgeo3, were expanded and
analyzed. Unless specified, the data presented in figures are derived
from cgeo1 heterozygotes.
Tg DNA analysis
Tail DNA was isolated according to standard protocols (Hogan et
al., 1986). For Southern blotting, 10 µg of DNA was digested for 24 hr at 37°C with 50 U of EcoRI (New England Biolabs,
Beverly, MA), and fragments were separated on 0.8% agarose gels and
transferred to Biodyne membranes (Life Technologies, Grand
Island, NY). Membranes were UV cross-linked and, after preincubation in
hybridization buffer (5× SSPE, 50% formamide, 5× Denhardt's
solution, and 1% SDS), were incubated with hybridization solution
containing 100 µg/ml salmon sperm DNA (5 Prime  3 Prime, Inc.,
Boulder, CO) and 106 counts/ml 32P
random prime-radiolabeled geo probe. Subsequently, blots were washed
and analyzed on a PhosphorImager (Molecular Dynamics, Sunnyvale, CA).
The geo random prime probe was generated by cutting pBKSgeo with
EcoRI and EcoRV and isolating and radioactively
labeling the 1.8 kb geo fragment.
To estimate Tg copy numbers, 10 µg of genomic DNA from each line and
12 pg (equivalent to about one copy) dilutions of the injected
muCNP-geo fragment (with non-Tg genomic DNA as a carrier) were
loaded onto a filtration manifold system (Life Technologies) and
transferred onto a Nytex membrane (Schleicher & Schuell, Keene, NH).
Membranes were incubated with 106 counts/ml
32P random prime-radiolabeled geo probe and washed as
described above. The integrated volume values for each band were
analyzed on a PhosphorImager (Molecular Dynamics).
PCR was performed on 0.5 µg of tail DNA using the HotStart
method (Life Technologies). The following oligonucleotide primers corresponding to the CNP promoter and geo regions were used to amplify a 313 bp sequence that was selectively amplified in Tg animals:
sense primer, 5'-ATCCTTGGAGCCAGAGACTAAG-3' ( 290
bp/HindIII); antisense primer, 5'-GCCATGTCACAGATCATCAAGC-3'
(+22 bp/HindIII).
PCR reactions were performed for 30 cycles (denatured, 94°C, 30 sec;
reannealed, 55°C, 45 sec; extension, 72°C, 1 min) using a final
concentration of 0.4 mM primers (Gene Link, Inc.,
Thornwood, NY), 0.25 mM dNTPs, 1.5 mM
Mg2+, and 1 U of Taq polymerase (Promega,
Madison, WI). Tail DNA from non-Tg mice from the same line and reaction
solutions devoid of DNA were run in parallel with experimental samples
and served as negative controls, whereas 0.5 ng of the muCNP-geo
construct was amplified as a positive control. After the PCR reaction,
samples were analyzed by electrophoresis on a 1.5% agarose gel.
Reverse transcription-PCR
Total RNA was isolated and processed according to the Tri
reagent method (Molecular Research Center, Inc., Cincinnati, OH) described by the manufacturer. The RNA was treated with RQ1 RNase-free DNase (1 U/µl; Promega) and was reverse-transcribed using the SuperScript preamplification system (Life Technologies) according to
the manufacturer's recommended protocol. Subsequently, 0.5 µg of
cDNA/tube was PCR-amplified as described above. Parallel samples were
prepared in the absence of reverse transcriptase to control for
nonspecific DNA amplification. The following primers were used: CNP I
sense primer, 5'-GGCTGGCTTTGAGGAGCC-3'; CNP II sense primer,
5'-AAAGGCGGTGACGGCGGTG-3'; CNP I/II antisense primer, 5'-GCCTTCCCGTAGTCACA-3'.
The CNP I and CNP II sense primers were used in combination with the
CNPI/II antisense primer to amplify a region of the endogenous CNP I
(830 bp) and CNP II (813 bp) coding sequences, respectively. Alternatively, they were used in combination with the antisense primer
described above for the DNA analysis to amplify a region specific to
the transgenic CNP I-geo (83 bp) or CNP II-geo (73 bp) coding
sequences (Fig. 1). Samples were analyzed on a 2% agarose gel.
Tissue culture
Culture media. Serum-containing media were composed
of DMEM (high glucose, 2 mM glutamine, and 110 gm/l
pyruvate), 10% heat-inactivated fetal calf serum, and 10 µg/ml
gentamycin (Life Technologies). Serum-free DMEM was formulated
according to the method of Cohen et al. (1996) and contained 25 µg/ml
apo-transferrin (Sigma, St. Louis, MO), 30 nM
triiodothyronine (Calbiochem, San Diego, CA), 20 nM
hydrocortisone (Sigma), 20 nM progesterone (Sigma), 10 nM biotin (Sigma), trace element B1
(Cellgro; Fisher, Pittsburgh, PA), 30 nM selenium (Sigma),
5 µg/ml insulin (Sigma), 1 µg/ml putrescine (Sigma), 0.1% BSA
(Life Technologies), and 10 µg/ml gentamycin. Conditioned media were composed of a 7:3 ratio (v/v) of fresh serum-free media and serum-free media obtained after 3 d incubation with either rat brain
astrocytes (Gard et al., 1990) or the B104 neuroblastoma cell line
(Bottenstein et al., 1988), respectively. For all cultures and
explants, cells were plated onto poly-D-lysine (Sigma; 10 mg/ml)-treated tissue culture dishes (Becton Dickinson, Lincoln Park,
NJ), and media were changed every 2 d. Cultures were maintained in
a humidified atmosphere (8% C02) at 37°C.
Embryonic OLs. Anesthetized embryonic day 12.5 (E12.5)
embryos were killed, and their brains were removed. The
rhombencephalon region (see Fig. 4A,
inset, blue region) was separated from the rest of the brain and was enzymatically digested at 37°C for 45-60 min in HBSS (Life Technologies) containing 12 U/ml papain (Sigma), 2 mM EDTA, 5.5 mM L-cysteine, and 20 mM HEPES, pH 7.4. The tissue was dissociated by trituration
and gravity-filtered through a 70 µm Nytex screening mesh (Tetco,
Briarcliff, NY). The filtrate was centrifuged at 200 × g for 10 min, and the pellet was resuspended in serum-free
DMEM containing 0.5% heat-inactivated fetal calf serum (Life
Technologies), 10 ng/ml recombinant human platelet-derived growth
factor-AA (Pepro Tech Inc., Rocky Hill, NJ), and 10 ng/ml recombinant
human glial growth factor (GGF; generously supplied by Dr. M. Marchionni, Cambridge Neuroscience, Cambridge, MA). Cells were plated
at a density of 6.5 × 105 cells/1.5 ml. After
24 hr, G418 (Life Technologies) was added at a final concentration of
180 µg/ml.
Postnatal OLs. Anesthetized postnatal day 10 (P10) mice were
killed, and their brains were removed. The cortices and brainstems were
stripped of meninges and gently teased apart using fine forceps. The
tissue was digested as described above and was gently triturated 3-10
times every 10-15 min. The suspension was diluted to a total volume of
50 ml with serum-containing media and was gravity-filtered successively
through 250, 150, and 75 µm Nytex screening mesh (Tetco). The
filtrate was centrifuged at 200 × g for 10 min, and the pellet was resuspended in
Ca2+/Mg2+ HBSS for further
manipulations. Alternatively, the cell pellet was resuspended in a 1:1
(v/v) solution of serum-containing media and either astrocyte- or
B104-conditioned media, at a density of 1.7 × 106 cells/ml, and was seeded (3 ml/dish) onto
60 mm tissue culture dishes (Becton Dickinson, Lincoln Park, NJ). The
cell suspension (two brains in 3 ml of HBSS/gradient) was gently
overlaid onto 10 ml of a 15% (2 ml)/60% (8 ml) Percoll gradient
(Pharmacia, Alameda, CA) in a 15 ml conical tube (Sarstedt, Newton, NC)
and centrifuged at 500 × g for 20 min. The interface
between the 15 and 60% Percoll layers was collected and diluted with
several volumes of plating media. The suspension was centrifuged at
200 × g for 10 min, resuspended, and washed in
serum-containing media. The cells were diluted 1:1 (v/v) solution of
serum-containing media and either astrocyte- or B104-conditioned media
to a density of 1.3 × 106 cells/ml and
plated (3 ml/dish) onto 60 mm dishes. After 24-36 hr cells were grown
in astrocyte- or B104-conditioned media supplemented with 1% FCS and
180 µg/ml G418 (Life Technologies). The G418 selection was performed
for up to 12 d in culture.
SCs. Sciatic nerves from P10 mice were dissected; the
epineurial sheaths were stripped off with fine forceps; and explants were maintained in serum-containing media. Once SCs began migrating off, the explants were transferred to new plates. Cells that had migrated onto the dishes were maintained in DMEM and 5% FCS
supplemented with 20 ng/ml GGF (Cambridge Neuroscience) and 2 µM forskolin (Calbiochem, La Jolla, CA) to promote cell
division and induce myelin gene expression, respectively (Mirsky et
al., 1980; McMorris, 1983; Lemke and Brockes, 1984; Morgan et al.,
1991; Marchionni et al., 1993). After 48 hr, 5-bromo-4-chloro-3-indolyl
galactopyranoside (X-gal) staining was performed on cultures to confirm
transgene activity, and, subsequently, G418 was added. When the G418
was used at a concentration of 180 µg/ml, fibroblast cell death was delayed; therefore, all studies were done using 360 µg/ml antibiotic.
Dissociated cultures of SCs were obtained from sciatic nerves that were
minced and incubated in HBSS containing 10 U/ml Papain (Sigma) and
0.03% collagenase (Life Technologies) at 37°C for 30 min. The
preparation was centrifuged, and the pellet was resuspended in
serum-containing media. The suspension was triturated five times,
passed through a 60 µm Nytex filter (Tetco), and centrifuged. The
pellet was resuspended in serum-containing media and plated onto a
60-mm-diameter tissue culture dish (Becton Dickinson). Cells were
maintained in serum-containing media supplemented with GGF (10 ng/ml)
and forskolin (2 µM). Forty-eight hours after plating, 360 µg/ml G418 was added to the cultures.
For all cultures, homozygous Tg males were mated with [C57BL/6J]
females, and the DNA from the heterozygous offspring was analyzed by
PCR to confirm the presence of the muCNP-geo transgene. Unless
specified, all analyses were done on cultures exposed to antibiotics
for up to 12 d.
Processing of tissue
For in vivo studies, mice were anesthetized and
killed, and the tissue was perfused with 4% paraformaldehyde in 10 mM phosphate buffer, pH 7.4. After a 24 hr incubation at
4°C, brains were washed with PBS and sectioned with a Vibratome (Ted
Pella Inc., Redding, CA). Alternatively, tissue was saturated with 20%
sucrose, mounted in Tissue-Tek mounting-freezing media (Miles, Inc.,
Elkhart, IN), and sectioned using a cryostat (Leica, Deerfield, IL).
For in vitro studies, tissue from mouse brains and sciatic
nerves were cultured and subsequently fixed with 4% paraformaldehyde in PBS for 30 min at 4°C before experimental assays.
-Gal substrate staining
DetectaGene Green staining was performed as recommended by the
manufacturer (Molecular Probes, Eugene, OR). Sections or cultures were
pretreated with 1 mM chloroquine to inhibit endogenous
lysosomal -gal activity. Subsequently, samples were incubated with
100 µM DetectaGene Green substrate reagent
[5-chloromethylfluorescein di--D-galacto-pyranoside
(CMFDG)], a green fluorogenic -gal substrate that reacts with
intracellular glutathione. The CMFDG-glutathione adduct is subsequently
converted by -gal to a fluorescent product that does not readily
cross cellular membranes. After a 1 hr incubation at 37°C, further
-gal activity was inhibited by the addition of 1 mM
phenylethyl -D-thio-galacto pyranoside, a competitive inhibitor of -gal. Incubation of tissue from non-Tg siblings served
as negative controls.
For X-gal staining, fixed sections or cultures were permeabilized with
2 mM MgCl, 0.01% sodium deoxycholate, and 0.02% NP-40. Subsequently, samples were incubated in staining solution, pH 7.0 [0.15 M NaCl, 10 mM
Na2HPO4, 17.5 mM
K3Fe(CN)6, 17.5 mM
K4Fe(CN)6, 2 mM MgCl, 0.01%
sodium deoxycholate, and 0.02% NP-40] containing 0.05% X-gal
(Promega) for between 2 and 24 hr.
Immunochemistry
For immunostaining procedures, fixed sections or cultures were
permeabilized with 0.5% Triton X-100 and blocked with diluent (10%
lamb serum, 10% calf serum, and 0.1% sodium azide in PBS). Sections
or cultures were incubated overnight at 4°C with the following
antibodies: -gal (rabbit polyclonal Ig, 1:200; 5 Prime 3 Prime),
CNP (mouse monoclonal IgG1, 1:400; Sternberger
Monoclonals Inc., Baltimore, MD), glial fibrillary acidic protein
(GFAP; mouse monoclonal IgG1, 1:400; Sigma),
neuron-specific enolase (NSE; rabbit polyclonal Ig, 1:10,000;
Polysciences, Inc., Warrington, PA), and S-100 (rabbit polyclonal,
1:250; Dako, Glostrup, Denmark). For live staining, cells were
incubated with 1 µg/ml affinity-purified A2B5 (mouse monoclonal IgM;
American Type Culture Collection, Rockville, MD) or O1 (mouse
monoclonal IgM; a gift from Dr. S. Pfeiffer, University of Connecticut,
Farmington, CT; Sommer and Schachner, 1981) for 20 min at 37°C. For
fluorescent detection of primary antibodies, the secondary antibodies
(Southern Biotechnology, Birmingham, AL) goat anti-rabbit IgG
fluorescein isothiocyanate (for -gal), goat anti-mouse
IgG1 tetramethylrhodamine isothiocyanate (TRITC, for CNP
and GFAP), goat anti-rabbit IgG TRITC (for NSE and S100), and goat
anti-mouse IgM µ-chain TRITC (for A2B5 or O1) were used at a dilution
of 1:200.
For bright-field immunodetection, endogenous peroxidase activity was
quenched with 0.3% H2O2 (Sigma). Subsequently,
sections or cultures were incubated with CNP (mouse monoclonal
IgG1, 1:200; Sternberger Monoclonals) or ED1 (mouse
monoclonal IgG1, 1:1000; Serotec, Raleigh, NC)
antibodies in 3% BSA, followed by incubation with biotinylated
secondary antibody (Vectastain ABC Elite kit; Vector Laboratories,
Burlingame, CA), ABC reagent, and peroxidase diaminobenzidine substrate
solution (Polysciences).
For all immunostaining, cell nuclei were stained with
4,6-diamidino-2-phenylindole (DAPI, 1:10,000 dilution; Sigma) in 1× PBS. Negative controls for each experimental condition consisted of
appropriate dilutions of secondary antibodies alone. Representative photographs reflect the results obtained from at least three
independent experiments in the cgeo1 and cgeo3 Tg lines.
Western analyses
Mice were killed under deep anesthesia by transcardiac perfusion
of saline for 5 min to flush out blood from tissue. Organs were
homogenized in 20 mM phosphate, pH 7.6, supplemented with 0.1% SDS, NP-40, and Triton X-100 and Complete protease inhibitors (Boehringer Mannheim, Indianapolis, IN).
For Western blot analysis, the indicated amount of protein for each
tissue or cell type examined was resolved by SDS-PAGE analysis on 10%
NuPage gels (Novex, San Diego, CA) and electroblotted at 30 V for 2 hr
(Novex) or overnight at 4°C (Bio-Rad, Cambridge, MA) onto
nitrocellulose (Micron Separations Inc., Westborough, MA). After the
transfer, gels were stained with Ponceau S solution (Sigma) as a
control for protein transfer. Membranes were placed in heat-sealed
polyethylene bags and blocked for 1 hr at 37°C with 1% (w/v)
Hammarsten-grade casein (BDH Chemicals Ltd., Poole, England) in PBS and
0.05% Tween 20 (blocking solution) and subsequently washed with
PBS and 0.05% Tween 20 (TPBS). Next, the primary antibodies -gal
(mouse monoclonal IgG2A, 1:1000; Promega), NPT II
(rabbit polyclonal IgG, 1:500; 5 Prime 3 Prime), and CNP (mouse
monoclonal IgG1, 1:10,000; Sternberger Monoclonals)
were diluted in staining solution (0.5% casein in TPBS) and added to
the nitrocellulose membranes. Blots were then incubated overnight at
4°C on an orbital shaker and washed the following day. The secondary
antibody, donkey anti-rabbit (for NPT II) or mouse (for -gal and
CNP) coupled to horseradish peroxidase (Jackson ImmunoResearch, West
Grove, PA), was diluted 1:10,000 in staining solution and incubated
with the membranes for 1-2 hr at room temperature. The blots were
washed once for 15 min and four times for 5 min each in PBS before 1 min incubation with an enhanced luminol solution (SuperSignal System;
Pierce, Rockford, IL). Then the blots were quickly dried, exposed to
x-ray film, and processed in an Eastman Kodak (Rochester, NY) automatic developer.
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RESULTS |
Establishment of the muCNP-geo transgenic lines
The muCNP-geo construct that was microinjected into the
pronuclei of fertilized eggs used the CNP promoters I and II to drive expression of a -gal and neomycin resistance (NPT) fusion protein (Fig. 1). Transcripts originating from
CNP promoter I of this construct would encode a protein in which the
geo initiation codon was used, whereas transcripts originating
from the CNP II promoter would initiate translation in exon 0 and
therefore contain nine amino acids of CNP fused in frame with
geo.
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Figure 1.
Schematic illustration of the muCNP-geo
construct used to generate Tg mice. The muCNP-geo construct was made
by ligating the NotI and HindIII fragment
of the muCNP promoter region, containing promoters I and II, to the
NotI and HindIII sites of the pBKSgeo
reporter gene encoding a protein with both -gal and neomycin
phosphotransferase activity. The regions to which primers were made
for the reverse transcription-PCR are marked with
black (upstream) and white (downstream)
arrowheads. The internal splice acceptor
(ISA) and the ATG translational start sites are
indicated. pI, muCNP promoter I; pII,
muCNP promoter II.
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Quantitative Southern blotting was used to identify variations in the
site of transgene integration and genotype (Fig.
2A-C). The integrated
volume for the 6 kb Tg radioactive band (Fig. 2A) for
each sample was divided by the integrated volume value for the total
amount of DNA in the lane (Fig. 2B, ethidium bromide staining), and the resulting ratios were plotted (Fig. 2C).
Genotype determination was first made by comparing values for the
heterozygous (Fig. 2A, single asterisk) parents to
that for their offspring (Fig. 2A, F2 generation).
Next, putative homozygous (Fig. 2A, double asterisks)
mice were mated with wild-type animals to confirm their genotype. Three
stable lines bearing ~6 (cgeo1), 20 (cgeo2), and 50 (cgeo3) copies of
the transgene (see Materials and Methods for copy number
determination), respectively, were independently bred and routinely
screened for the presence of muCNP-geo by PCR analysis of genomic
tail DNA (see Materials and Methods). -gal expression was less
robust in cgeo3 compared with cgeo1 (data not shown), indicating that
in our system there was no direct correlation between copy number and
transgene expression. Within all three lines, Tg animals were fertile
and appeared normal throughout their development.
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Figure 2.
Southern blot analysis of the cgeo 1 Tg line.
A, PhosphorImager analysis of
EcoRI-digested genomic DNA (stained with ethidium
bromide B). EcoRI cut the transgene
twice, producing a 6 kb band in Tg that was not detected in non-Tg
mice, using the geo probe. One asterisk indicates
heterozygous; two asterisks indicate homozygous, and the
absence of asterisks indicates a non-Tg sibling. F0,
founder; F1, F1 generation; F2, F2
generation. C, The integrated volume for the 6 kb Tg
radioactive band for each sample was divided by the integrated volume
value for the total DNA in the lane, and the resulting ratios were
plotted. D, Total RNA was extracted from the brains of
P21 Tg mice or non-Tg littermates, and the level of expression of
CNP I, CNP II, CNP I-geo, or CNP II-geo was analyzed by
reverse nscription-PCR. The endogenous CNP I and CNP II sequences were
amplified in both the Tg and non-Tg samples, as shown by a positive
band at ~800 bp. By contrast, the CNP I-geo (83 bp) and CNP
II-geo (73 bp) sequences were present only in Tg mice. Reactions run
in the absence of reverse transcriptase (RT) showed no amplified
band.
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muCNP-geo promoter efficacy and tissue-specific expression of
the geo protein
Total RNA from P21 mouse brain was reverse-transcribed and
analyzed by PCR to determine the transcriptional efficacy of the CNP
promoter region. Using primers to amplify part of the endogenous CNP I
or CNP II coding sequences, bands at the correct size (~800 bp) were
present in both the non-Tg and Tg tissue (Fig. 2D).
In the presence of primers specific for the transgene coding sequence (Fig. 1), a band of the correct size for both CNP I-geo (83 bp) and
CNP II-geo (73 bp) was amplified only in the transgenic samples and
only in the presence of reverse transcriptase (Fig.
2D). These results provide evidence that both the CNP
I and CNP II promoters were capable of driving the transcription of the
geo fusion gene.
X-gal staining of freshly isolated protein from P55 Tg and non-Tg
control tissue (Fig. 3A)
demonstrated transgene activity in the brain, spinal cord, sciatic
nerve, and thymus in Tg mice. P21 mice were examined by Western
blotting to determine whether muCNP-geo drives the translation of
the geo fusion gene in Tg animals. Using antibodies raised against
either -gal or NPT II (neomycin resistance; Fig. 3B), a
doublet at the estimated size for the geo fusion protein (150 kDa)
was observed only in Tg animals and was absent from control spinal
cord. Similar results were observed in three independent preparations
(results not shown), suggesting that these bands arose from the
transcriptional activity of promoters I and II. Alternatively, these
findings could reflect distinct modifications of one of the protein
species or protein degradation.
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Figure 3.
Immunoblot analyses on tissue from Tg and non-Tg
mice. A, Total protein (700 µg) was transferred from a
P55 Tg mouse to a nylon membrane and incubated with X-Gal. The brain,
spinal cord, sciatic nerve, and thymus showed greatly increased -gal
activity compared with the same tissue from non-Tg siblings.
B, To examine the presence of the geo fusion protein
in Tg animals, 12 µg of total protein from P21 Tg or non-Tg sibling
animals was resolved on a 7.5% acrylamide gel, electrotransferred, and
probed for both -gal and NPT II. The blots were processed for
chemiluminescent detection and exposed to film for 10 min. Using either
-gal or NPT II antibodies, immunoreactive bands, corresponding to
the appropriate size for the geo fusion protein (~150 kDa), were
found only in Tg spinal cord and were absent from control tissue.
C, When blots were probed for CNP, protein levels were
similar in both Tg and control mouse tissues. Blots were exposed for 10 sec (brain, spinal cord, and sciatic nerve) and 1 hr (testis, kidney,
spleen, liver, heart, lung, and thymus). Horizontal
arrows delineate approximate molecular weights.
C, Non-Tg littermate control; ScN,
sciatic nerve; SpC, spinal cord. Similar results were
observed in four independent experiments.
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Genomic integration and expression of the muCNP-geo transgene did
not appear to alter the levels of CNP protein in any of the tissues
examined. Similar patterns of expression of the 46 and 48 kDa species
were observed in both Tg and control tissues (Fig. 3C). Both
the CNP I-immunoreactive (46 kDa) and CNP II-immunoreactive (48 kDa)
species were found in the brain, spinal cord, and sciatic nerve.
Moreover, consistent with reports of CNP expression in the non-neural
tissues thymus and testis (Bernier et al., 1987; Vogel and Thompson,
1988; Sprinkle, 1989; Scherer et al., 1994), a band migrating around
that of CNP I (46 kDa) was observed in these tissues as well as in
spleen, lung, and liver (Fig. 3C). However, excluding the
spleen, protein levels were considerably lower than in the brain or
peripheral nerve. A smaller immunoreactive band (<46 kDa) was also
present in these tissues that could reflect degradation, a
product with distinct post-translational modifications, or nonspecific
cross-reactivity.
Of the three transgenic muCNP-geo lines, cgeo1 expressed the
transgene at the highest level and, consequently, was expanded for
further study. However, the developmental and tissue-specific expression of geo was similar in all three lines.
Tagging oligodendrocytes and Schwann cells with the
-galactosidase reporter
muCNP-geo -gal activity was observed early during
development. In sagittal sections of E12.5 mice,
lacZ-positive cells were observed in the CNS. Two distinct
columns of blue cells were evident in the ventral region of the
rhombencephalon (Fig. 4A,
arrow, asterisk; A corresponds to the
highlighted, blue, region in the inset). A band
of transgene-positive cells continued caudally along the region of the
ventral spinal cord (Fig. 4B, arrowhead) and floor
plate (Fig. 4B, asterisk), with additional blue cells scattered in the ventral mantal layer. Blue staining present around the
floor plate region (Fig. 4B,D, asterisk) may
represent radial glial projections (Kurtz et al., 1994). Several
lacZ-positive cells were also present in the telencephalon,
adjacent to the third ventricle (results not shown). In the PNS,
transgene activity was present predominantly in ventral projections of
the spinal cord ganglia (Fig. 4C).
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Figure 4.
LacZ staining in muCNP-geo
embryos. A-C, Whole-mount sagittal sections from E12.5
Tg embryos. A, In the brain, -gal activity was found
in the ventral regions of the rhombencephalon (arrow,
asterisk; this region corresponds to the blue
area depicted in the inset). B,
In the spinal cord, lacZ-positive cells were evident in
the ventral (arrowhead) and floor plate
(asterisk) regions. C, In the PNS, blue
cells were present in neural crest cells surrounding and projecting
ventrally off the spinal cord ganglia. D-H, Whole-mount
sagittal sections from E15 Tg mice. D, Transgene activity was present in the lower thoracic
spinal cord in the ventral (arrowhead) and floor plate
(asterisk) regions. In the PNS, transgene activity was
found in cranial nerves (E, long arrow, F) and
peripheral nerve projections (E, arrowheads, F, G).
H, Whole-embryo X-gal staining of a non-Tg E15 sibling
showed no endogenous -gal activity. Cranial nerves:
V, trigeminal; VII, facial;
VIII, vestibulocochlear; IX,
glossopharyngeal; XII, hypoglossal. Cervical nerves:
bp, brachial plexus; cp, cervical plexus.
Sections were 200-µm-thick. Scale bars: A, 350 µm;
B, D, 700 µm; C, 250 µm; E,
H, 3.0 mm; F, 900 µm; G, 2.0 mm. Similar results were seen in three embryos per time point, each
using different mating pairs.
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At E15, in the CNS strong lacZ staining was observed in
cells within the ventral spinal cord (Fig. 4D,
arrowhead) and around the floor plate (Fig. 4D,
asterisk) at the level of the lower thoracic (Fig.
4D), lumbar, and sacral spinal cord. Minimal
transgene activity was detected in the cervical spinal cord or in
higher cortical regions (results not shown). In the PNS, -gal
activity was observed throughout the rostral to caudal extent of the
spinal cord in peripheral nerve fibers projecting both dorsally and
ventrally (Fig. 4E, arrowheads, F,G) and in cranial
nerve projections (Fig. 4E, arrow, F). At both
E12.5 and E15, lacZ-positive cells were also observed in
cells within the intercostal nerves, liver, inner ear, adrenal medulla,
and eye (results not shown). Staining was absent from non-Tg
littermates at the same age (Fig. 4H).
Immunohistochemical studies were performed on P21 mice to characterize
the cellular distribution of -gal staining throughout the postnatal
brain (Figs. 5, 6) and sciatic nerve
(Fig. 7). For all immunochemistry, staining was absent from negative
controls in which the primary antibody was omitted. Coronal sections of the CNS showed robust lacZ staining in white matter tracts
of the cortex (Fig. 5A), brainstem (Fig. 5B), and
cerebellum (Fig. 5B) that was indistinguishable from CNP
expression patterns (Trapp et al., 1988; Vogel and Thompson, 1988).
Moreover, robust -gal activity was present in white matter tracts of
13-month-old Tg animals from each line (results not shown), the latest
time point examined. Higher-power magnification of the cortical region
shown in Figure 5A confirmed lacZ-positive cells
(blue) in CNP-positive (brown) OLs (Fig.
5C,D). Double immunostaining with CNP (Fig. 5E)
and bacterial -gal (Fig. 5F) antibodies
demonstrated the co-localization of these antigens to individual OLs
(arrow, arrowhead).
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Figure 5.
Tg -gal staining in oligodendrocytes in
vivo. X-gal staining (blue) of 40-µm-thick
coronal sections from cortex (A), brainstem
(B), and cerebellum of a P21 mouse showed -gal
activity throughout CNS white matter tracts. Higher-power
magnifications of muCNP-geo promoter activity in the cortex
(C) and in an individual cell
(D) demonstrated that -gal activity
(blue) was localized to CNP-positive
(brown) OLs. Note that the cell bodies and arborized
processes of the CNP- and X-gal-positive cells are characteristic of
OLs. Indirect immunofluorescence of a section double-labeled with
CNP-specific (E) and -gal-specific
(F) antibodies demonstrated co-localization of
these two antigens within the same cells (arrow,
arrowhead). G, Overlay of the -gal and CNP
double immunostaining shown in E and F.
H, DAPI staining of the individual cell nuclei in the
section shown in E-G. Scale bars: A, 1.6 mm; B, 800 µm; C, E-H,
40 µm; D, 10 µm. ac, Anterior
commissure; bs, brainstem; cb,
cerebellum; cc, corpus callosum; cp,
caudate putamen; cx, cortex; lot, lateral
olfactory tract; lsn, lateral septal nucleus;
msn, medial septal nucleus. Similar results were seen in
five independent preparations.
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Double immunostaining of P21 brain sections with neuron-specific (NSE;
Fig. 6A), astrocytic
(GFAP; Fig. 6C), or microglial-specific (ED1; Fig.
6E) markers showed no co-localization with the
-gal substrates CMFDG (Fig. 6A,C) and X-gal (Fig.
6E) in the CNS. DAPI staining of cell nuclei in each
field was used to identify individual cells (Fig.
6B,D,F).
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Figure 6.
Tg -gal activity in neurons, astrocytes, and
microglia in vivo. Forty-micrometer-thick coronal
sections from the brains of P21 mice were double-stained with either
the -gal substrate CMFDG or X-gal and NSE, GFAP, or ED1-specific
antibodies. CMFDG (A, C, fluorescent green) or
lacZ (E, blue) staining did not
co-localize to (A) NSE-positive neurons
(A, fluorescent red), GFAP-positive astrocytes
(C, fluorescent red), or ED1-positive microglia or
monocytes (brown) in the cerebrum. B, D,
F, DAPI staining (fluorescent blue) of
individual cell nuclei in A, C, and D,
respectively. Top, Dorsal; bottom,
ventral. A, B, Caudate putamen; C, D,
corpus callosum; E, F, brainstem just below fourth
ventricle. Scale bar, 50 µm. Similar results were seen in five
independent preparations.
Figure 7.
Double immunostaining of a transverse section from
a Tg postnatal 2 month sciatic nerve (10-µm-thick section)
demonstrating -gal-positive (A) and
S-100-positive (B) SCs (e.g., see
arrow in A-C). C,
Phase-contrast photomicrograph of corresponding field shown in
A and B. D, Longitudinal
section from a P17 sciatic nerve demonstrating -gal activity along
the length of a Schwann cell internode (20-µm-thick section). Scale
bar: A-C, 30 µm; D, 50 µm. Similar
results were seen in three independent preparations.
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In P17 (Fig. 7D) and P2 month
(Fig. 7A-C) sciatic nerve, -gal immunoreactivity (Fig.
7A) and transgene activity (Fig. 7D) were
localized to S-100-positive (Fig. 7B) SCs and were not
present in Thy 1.1-positive fibroblasts (results not shown).
Staining was observed along the length of the Schwann cell internode
(Fig. 7D).
The half-life of the -gal enzyme varies depending on the cell type
in which it is expressed and the nature of the amino acid at the N
terminus of -gal and, in vivo, has been reported to range
from 3 min to 20 hr (Bachmair et al., 1986). At P10, when both CNP I
and II are expressed (Scherer et al., 1994) and the muCNP-geo
transgene was strongly expressed in vivo, there was a rapid
decrease in -gal expression in SCs within 12 hr after they were
removed from the animal. These results indicate that in our model the
-gal turnover was relatively rapid and that the muCNP-geo
expression patterns reported corresponded well to promoter activity.
The different levels of CNP expression observed between individual OLs
(Fig. 5E, arrow vs arrowhead) or SCs (Fig. 7)
could reflect spatial differences in the distribution of CNP within individual cells that are evident depending on the plane of view of the
section. Alternatively, these differences could represent heterogeneity
in the OL or SC phenotype. -Gal immunoreactivity, however, was
present in all CNP-positive (for OLs) or S-100-positive (for SC) cell
bodies identified within each field.
Selecting oligodendrocytes with the neomycin
phosphotransferase reporter
A strong band of transgene-positive cells was detected in the
rhombencephalon at E12.5 (Fig. 4A, inset, blue area);
therefore, cells were isolated from this brain region and developmental
stage and cultured in serum-free DMEM containing GGF and PDGF to
determine whether they would differentiate into OLs (Fig.
8). After 3 d in culture
transgene-positive cells were identified (Fig. 8A,B), and after 9 d exposure to G418, most of the viable cells were lacZ-positive (Fig. 8C,D) or -gal-positive
(Fig. 8E,G). Double immunostaining demonstrated the
presence of -gal-positive cells that were A2B5-negative (arrow, Fig.
8E,F, arrows) or cells characterized by a more
rounded soma that were A2B5-positive (Fig. 8E,F,
arrowheads). Further characterization showed the presence of more
differentiated -gal- and O1-positive OLs (Fig. 8G,H,
arrows). All lacZ-negative or A2B5 single-positive
cells appeared to be dead or dying as determined by their round,
phase-bright appearance or negative DAPI stain (Fig. 8C-F,
arrowheads and top right). When cultures were grown in
the presence of neural basal media or serum-containing media alone, no
transgene-positive cells were detected (data not shown).
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Figure 8.
In vitro selection and antigenic
characterization of transgene positive-cells from E12.5
rhombencephalon. A, B, Phase-contrast
(A) and corresponding bright-field
(B) photomicrographs of dissociated
rhombencephalon cultures showing lacZ-positive staining
(arrow) after 3 d in culture and 48 hr exposure to
G418. C, D, Phase-contrast
(C) and corresponding bright-field
(D) photomicrographs of cells taken after 9 d exposure to G418, demonstrating that most of the surviving cells were
-gal-positive. Transgene-negative cells were round and phase-bright
in appearance (C, D, arrowheads), and many lacked an
identifiable cell nucleus (red cells; E, F, top
right). Double immunostaining showed that
(E) -gal-positive cells were A2B5-negative
(E, green cells, arrow) or A2B5-positive
(E, yellow, arrowheads). Additionally,
many cells were positive for both -gal and O1 (G,
yellow fluorescence). F, H, DAPI
staining of the individual cell nuclei shown in E and
G, respectively. Scale bar: A, B, E-J,
50 µm; C, D, 90 µm. Similar results were seen in two
independent preparations.
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The activity of the NPT portion of the geo fusion protein was also
examined by culturing mixed cells obtained from P10 mouse brains in the
presence of the antibiotic G418. Cells from the CNS were grown in the
presence of either B104 or astrocyte-conditioned media. Within 24-36
hr after plating, 180 µg/ml G418 was added, and cell survival was
assayed. In non-Tg mouse cultures, within 3 d of exposure to the
antibiotic there was extensive cell death, and after 8 d there was
no cell survival. In muCNP-geo mice, -gal-positive cells (Fig.
9A,B) were present among the
adhering heterogeneous population. The total number of OLs or other
cell types were added from 15 random fields at various times after the
addition of 180 µg/ml G418 (Table 1).
Sister cultures were fixed and stained with X-gal or anti-CNP antibody
to assess transgene activity and OL morphology, respectively, for cell
counts. Before the addition of G418, it was difficult to discern
individual OLs because of the large number of other cell types in the
dish (>70%); therefore, cell counts were not done in the absence of
antibiotics. However, after 4 d of G418 treatment, OLs could be
clearly distinguished from other cell types, and cell counts were
obtained.
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Figure 9.
In vitro selection of
transgene-positive oligodendrocytes in P10 Tg mice. A,
B, Phase-contrast (A) and
corresponding bright-field (B) photomicrographs
of dissociated brain cultures 24 hr after plating. The heterogeneous
cellular fraction contained lacZ-positive cells
(blue) that were round to spindle-shaped cells and
contained few extended processes. After 12 d exposure to 180 µg/ml G418, surviving cells were positive for both
lacZ (C, phase-contrast;
D, bright-field) and, using indirect immunfluorescent
microscopy, CNP (E). F, DAPI
staining of individual nuclei within the same field as
C-E confirmed cell number. In the presence of
B104-conditioned media, many cells contained multipolar processes
(C-F, arrowheads). G, H, Phase-contrast
(G) and bright-field
(H) G418-selected cultures grown in the
presence of astrocyte-conditioned media contained -gal-positive
progenitor cells (arrow) with bipolar processes and more
differentiated cells (arrowhead). Scale bar, 50 µm.
Similar results were seen in six independent preparations.
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Cells that were collected from a Percoll gradient (refer to Materials
and Methods) and grown in B104-conditioned media were analyzed
quantitatively, and the total number of OLs did not significantly change after 12 d of exposure to G418 (Table 1, B104). By
contrast, within 4-5 d after exposure to the antibiotic, there was a
significant (p < 0.001) decrease in the number
of other cells types in the dish. At 12 d of exposure to G418,
cultures were fixed and stained, and 99% of the surviving cells were
both -gal-positive (Fig. 9C,D) and CNP-positive (Fig.
9E) OLs (arrowhead). DAPI staining (Fig.
9F) of individual nuclei confirmed cell numbers.
Cells grown in astrocyte-conditioned media and G418 were analyzed
quantitatively. In preparations in which cells were plated directly
after filtering (refer to Materials and Methods), the total number of
OLs dramatically increased over time (Table 1, ACM, a). The
morphology of surviving OLs varied from round bipolar
"progenitor-like" cells (Fig. 9G,H, arrow) to more
differentiated cells containing multipolar arborized processes (Fig.
9G,H, arrowhead). In preparations that were collected from a
Percoll gradient, there was a significant increase in the number of OLs
12 d after the addition of the antibiotic. However, OL cell
numbers were lower than in the preparations in which cells were plated
directly after filtering (Table 1). Under both conditions, within
7 d there was a significant (p < 0.001) decrease in the number of cells that were not OLs. In all preparations, cultures were fixed and stained after 12 d of exposure to G418, and only between 0 and 1.4% (Table 1) of the surviving cells were
-gal- and CNP-negative.
Conditioned media from B104 neuroblastoma cells or
rat astrocytes stimulates cell division in OL progenitor cells
(Botten- stein et al., 1988; Gard et al., 1990, 1995). However,
in preparations that were run through a Percoll gradient,
B104-conditioned media did not significantly increase the number of OLs
(Table 1). Moreover, in astrocyte-conditioned media, after antibiotic
selection there were many more progenitor cells in preparations that
were filtered compared with those that were subsequently run through a
Percoll gradient (Table 1). Because Percoll separates cells based on their density, this step may have preferentially selected for the more
buoyant, differentiated OLs (Maric et al., 1997). Moreover, increased
numbers of OLs may be generated more efficiently by using younger
animals, because at P10 cells begin to differentiate, and once placed
in vitro, many may not respond to mitogens
as robustly as in earlier stages of development.
When OL cultures were exposed to G418, there was substantial astrocytic
cell death and a dramatic increase in cellular debris. Rinsing the
dishes several times every 2 d during feedings eliminated debris.
In preparations in which cells were plated directly after filtration,
initially there was relatively more debris compared with the Percoll
preparations. However, over time cellular debris was washed away with
media changes, and both progenitor and more differentiated cells were
present after G418 selection. Thus, filtration and selection alone were
sufficient to generate pure populations of OLs. In preparations of
optic nerve OLs (K. J. Chandross, R. I. Cohen, and L. D. Hudson,
unpublished observations) and sciatic nerve SCs there was minimal
debris, and dying cells were easily removed when the media were replaced.
Selecting Schwann cells with the neomycin
phosphotransferase reporter
Transgene activity was clearly evident in P10 sciatic nerve (data
not shown); however, it was barely detectable in culture once cells
migrated off explants and began to dedifferentiate (data not shown).
Therefore, after cells began to migrate onto the dish, explants were
removed, and the cultures were supplemented with GGF and forskolin. Two
waves of SC migration off the explants were analyzed (Table
2), the first occurring within 1 week and the second within 2 weeks after dissection. Within 48 hr,
lacZ-positive cells were detected (data not shown), and G418
was added to the cultures (Fig.
10A). Before the
addition of antibiotics, cultures consisted of between 48% (Table 2,
primary migration) and 23% (Table 2, secondary migration) fibroblasts.
In non-Tg cultures all cells died within 8 d of exposure to the
antibiotic. In preparations from muCNP-geo heterozygous mice, 3 d after the addition of G418, fibroblasts were still present in the
cultures (Table 2, Fig. 10B-D); however, in contrast
to Schwann cells they were negative for the fluorescent -gal product
CMFDG (Fig. 10B-D, arrow) and S-100 (results not
shown). Within 8 d, only 1% of the cells were fibroblasts (Table
2). At 12 d of exposure to G418 (Fig.
10E-H), cells were fixed and stained, and
surviving cells were -gal-positive (CMFDG, Fig.
10F) and S-100-positive (Fig. 10G) SCs.
DAPI staining of individual nuclei (Fig.
10D,H) confirmed cell numbers. After 12 d, the G418 was removed, and SCs were expanded in the presence of
forskolin and GGF. When analyzed after 21 d, surviving cells continued to express the transgene (results not shown), and only 0.2%
of the cells were fibroblasts. Moreover, in dissociated SC cultures,
within 1 week after adding G418, 99% of the cells were S-100- and
-gal-positive SCs.
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Figure 10.
In vitro selection of
transgene-positive Schwann cells in P10 muCNP-geo mice.
(A) Before selection, the phase-contrast
photomicrograph shows that cultures contained Schwann cells
(arrowhead; spindle-shaped, bipolar cells) and
fibroblasts (arrow; flat, multipolar cells).
B-D, Within 3 d of exposure to 360 µg/ml G418,
SCs were positive, whereas fibroblasts (B-D, arrow)
were negative for CMFDG (C). D,
The corresponding field from A and B,
stained with DAPI, demarcates individual cell nuclei.
E-H, At 12 d of exposure to G418
(E, phase-contrast), surviving cells were positive for
both CMFDG (F, fluorescent micrograph) and S-100
(G, fluorescent micrograph). H,
Corresponding field from E-G, stained with DAPI,
demarcates individual cell nuclei. Scale bar, 50 µm. Similar results
were seen in three independent preparations.
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DISCUSSION |
The muCNP promoter effectively drives the expression of a geo
fusion protein in Tg mice, allowing for the simultaneous detection (-gal) and selection (neomycin resistance) of OLs and SCs. Our results demonstrate the effectiveness and sensitivity of this system
for analyzing glial cell lineage progression, migration, and fate, both
in vitro and in vivo. For example, the
transgene-positive cells identified at E12.5 within the ventral
rhombencephalon are OL progenitors, as defined by their ability to
differentiate into OLs in vitro under selective conditions.
Moreover, the data show in general that cell-specific promoters can be
used as a powerful tool for the rapid and efficient selection of mouse
OL and SC in vitro.
CNP in muCNP-geo mice
Transcription of the CNP gene is initiated at two separate
promoters; the upstream driving expression of a 2.4 kb CNP II mRNA species and the downstream resulting in transcription of a 2.6 kb CNP I
mRNA species (Kurihara et al., 1990). The 2.6 kb transcript encodes a
46 kDa CNP I protein isoform (Monoh et al., 1989; Kurihara et al.,
1990; Gravel et al., 1994), whereas the 2.4 kb mRNA can direct the
synthesis of both the 46 kDa CNP I and the 48 kDa CNP II protein
isoforms (O'Neill et al., 1997). Although CNP I is the most prominent
mRNA and protein found in OLs and SCs, CNP II mRNA and protein are also
expressed by these cells, and CNP II is the only mRNA isoform
characterized to date that has been described in precursor cells
(Scherer et al., 1994). Both CNP promoters become increasingly active
postnatally, coincident with observed increases in protein expression,
the onset of cellular differentiation, and myelination (Braun et al.,
1988; Jordan et al., 1989; Sprinkle, 1989; Hardy and Reynolds, 1991;
Tsukada and Kurihara, 1992; Scherer et al., 1994).
CNP II is the only mRNA species detected in non-neural tissues (Scherer
et al., 1994; Gravel et al., 1998; present study); however, CNP I is
the predominant polypeptide identified in these tissues (O'Neill et
al., 1997). Myelin gene expression has been reported in immune tissue
(Pribyl et al., 1993, 1996; Kuramoto et al., 1997; Kalwy et al., 1998),
and consistent with previous reports of CNP expression in the thymus
(O'Neill et al., 1997), in muCNP-geo Tg mice, lacZ
staining was present in the thymus, liver, and spleen. Moreover, in
E12.5 and E15 embryos, -gal activity was detected in the eye,
adrenal gland, and liver, indicating a role for CNP outside of the
nervous system at early stages of development. These results suggest
that the muCNP-geo mice can be useful to further identify and purify
non-neural cell types in tissues in which the CNP promoter is active
and to help delineate the function of CNP.
In the nervous system, transgene expression is restricted to
oligodendrocytes and Schwann cells
In all postnatal Tg neural tissue examined, both CNPI-geo and
CNPII-geo mRNA were present, indicating that both promoters were
active. Furthermore, anti--gal- or NPT II-immunoreactive species,
migrating at the expected molecular weight (~150 kDa), were also detected.
In the mouse CNS, CNP mRNA is detected at E12 (Peyron et al., 1997),
and, subsequently, immunoreactivity is observed at E14 (Yu et al.,
1994), coincident with the expression of the PDGF- receptor (Yu et
al., 1994) and presumably the onset of glial cell development. In the
muCNP-geo mice, transgene activity was evident within the brain,
spinal cord, and neural crest derivatives at E12.5, earlier than
previously reported for CNP protein expression. In the CNS, positive
lacZ staining formed a continuous longitudinal column of
cells along the ventral domain of the CNS, beginning at the level of
the rhombencephalon and continuing caudally along the extent of the
spinal cord. There is evidence that in the spinal cord OLs are derived
from a restricted region of the ventricular zone, near the floor plate
(Warf et al., 1991; Noll and Miller, 1993; Pringle and Richardson,
1993; Yu et al., 1994; Timsit et al., 1995; Peyron et al., 1997). The
onset of muCNP-geo expression coincided spatially with the
expression of known OL markers and ventrally derived growth factors
believed to be important for their development (Stemple and Anderson,
1992; Yu et al., 1994; Orentas and Miller, 1996; Richardson et al.,
1997), indicating that the transgene-positive cells expressed at E12.5
and E15 represent OL progenitors.
Temporal and spatial information regarding the origins of OLs in the
brain is limited. PDGF- receptor- and DM-20-expressing cells in the
germinative neuroepithelium are believed to be OL precursors (Peyron et
al., 1997), but expression of these markers may not be absolutely
limited to glial cells (Johe et al., 1996; Williams et al., 1997). By
culturing cells from E12.5 rhombencephalon in the presence of
antibiotic, we clearly demonstrated that the transgene-positive cells
from this region represent a foci of progenitors capable of
differentiating into mature OLs. This discrete population may arise
from the migration of cells into the brain from the spinal cord before
E12.5, or they may represent a distinct population. The presence of OL
progenitors in the rhombencephalon at E12.5, together with the limited
number of transgene-positive cells observed throughout the rest of the
brain at this developmental stage (e.g., small population in the
telencephalon), suggests that the rhombencephalon may be an important
source of OL in the brain. Several studies support a role for distinct
pools of OL progenitors in the brain (Privat and Leblond, 1972; Pringle
and Richardson, 1993; Timsit et al., 1995; Peyron et al., 1997).
Transgene activity was also observed in neural crest progenitor cells
at E12.5, indicating that the CNP promoter region used was active in SC
precursors and may be useful for studying their development.
The temporal expression pattern of the muCNP-geo transgene highly
correlated with CNP, with lower levels of -gal activity early in
development and increased transgene activity postnatally. The
muCNP-geo transgene activity observed early during development may
reflect increased sensitivity to low-level promoter activity amplified
by the -gal enzyme compared with CNP immunostaining. Although this
level of detection may not represent physiologically relevant promoter
activity, low levels of myelin-related mRNAs and proteins were reported
in both precursors of OLs (Yu et al., 1994; Timsit et al., 1995;
Hajihosseini et al., 1996; Parmantier et al., 1997; Peyron et al.,
1997) and SCs (Landry et al., 1997; Lee et al., 1997). Previous
developmental studies examining CNP expression may have been limited by
the sensitivity of the available probes and antibodies.
muCNP-geo oligodendrocytes and Schwann cells
are antibiotic-resistant
Several different strategies have been used to selectively isolate
individual cell types from a heterogeneous population. For example,
enrichment procedures take advantage of the ability of one cell type to
preferentially attach to a substrate (McCarthy and De Vellis, 1980;
Sasaki et al., 1989). However, it may take several weeks to optimize
the purity of these cultures, especially when taking into consideration
the subsequent manipulations that are necessary to generate pure
populations of mouse, rather than rat, OLs (Levison and McCarthy, 1992;
Gard et al., 1995). Immunopanning (Mage et al., 1977; Wysocki and Sato,
1978; Barres et al., 1992), immunomagnetic (Meier et al., 1982;
Chalazonitis et al., 1994; Wright et al., 1997), and
fluorescence-activated cell sorting (Abney et al., 1983) techniques use
the expression of surface molecules to select specific cell types.
Although these approaches can be effective, they can be costly and are
limited by cell-specific surface epitopes and the availability of the
corresponding antibodies. Furthermore, fluorescence-activated cell
sorting requires costly specialized equipment and highly trained
personnel. Although many selection strategies when applied properly
yield large numbers of OLs and SCs, they can be harsh on cells, and a
compromise must be made with regard to viability, the level of purity,
and yield. By contrast, within 8-9 d of exposure to G418, we were able
to generate large numbers of tagged, antibiotic-resistant OL and SC
cultures that were 99% free of other cell types, a strategy that is
not limited by antibody specificity or complicated procedures. Moreover, in the presence of mitogens, increased cell numbers were
observed; thus cells can be expanded as they are being selected.
In general, separation procedures may be characterized by inherent
biases that preferentially optimize for the selection of a particular
phenotype, rather than an individual cell type. For example, in
vivo the CNP II promoter is turned on in the developing nervous
system, whereas CNP I promoter activity is restricted to
differentiating cells (Scherer et al., 1994); thus, in vitro the weakly expressing progenitors may have been more sensitive to the
dose of G418. However, in the muCNP-geo preparations, the
concentration of G418 did not preferentially select only the most
robustly expressing cells (e.g., the more-differentiated cell types).
We observed lacZ staining in the E12.5 embryo, and, when
cultured, these OL progenitors were resistant to antibiotics. Moreover,
for all of the culture preparations, the morphology of surviving OLs or
SCs varied from progenitor-like to more differentiated and both
dividing and mitotically quiescent cells were present. All
antibiotic-resistant OLs and SCs expressed some -gal activity; however, there was heterogeneity in the level of lacZ
staining. Further analysis with several different developmentally
homogeneous cell populations should clarify whether this reflects
differences in the levels of transgene expression related to the
developmental stage of cells or, alternatively, mosaicism.
In toto, these results suggest that the muCNP-geo mice provide a
sensitive, quantitative approach to detecting cells, especially at
early stages of neural development when detection is defined by the
limited sensitivity of available probes. Preliminary studies demonstrate that this system is useful for tracing the origin and
migratory routes of cells during their ontogeny. Moreover, at different
stages of development cells can be isolated, selected, and studied
in vitro. Additionally, the muCNP-geo transgene may be
crossed into a range of transgenic mouse lines, including conditional knock-out lines in which the neo cassette can be excised out. The
muCNP-geo Tg may also be useful for examining the temporal and
spatial signals that regulate CNP expression. In contrast to the other
available techniques for purifying mouse OLs and SCs, after selection
the muCNP-geo cells are tagged and, therefore, may be useful for
subsequent co-culture, transplantation, lineage, and promoter activity analyses.
| |
FOOTNOTES |
Received Aug. 25, 1998; revised Sept. 25, 1998; accepted Oct. 26, 1998.
This study was supported by National Institute for Neurological
Diseases and Stroke intramural funds. R.I.C. was supported by National
Multiple Sclerosis Society Grant FG1197-A1. We thank Dr. P. Soriano for
generously supplying the pBKSgeo construct, Dr. M. Marchionni for
the GGF, and Dr. S. Pfeiffer for the O1 antibody. Thanks to Melissa
Comiso for technical assistance and Drs. D. Agoston, H. Arnheiter,
B. Y. Champagne, J. A. Kessler, I. Maric, D. Maric, E. Mezey,
U. Pott, M. E. Rubio, and A. Zimmer for helpful discussions and advice.
Correspondence should be addressed to Dr. Karen J. Chandross,
National Institutes of Health, National Institute for Neurological Diseases and Stroke, Laboratory of Developmental Neurogenetics, Building 36, Room 5D21, Bethesda, MD 20892.
| |
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N. S. Roy, S. Wang, C. Harrison-Restelli, A. Benraiss, R. A. R. Fraser, M. Gravel, P. E. Braun, and S. A. Goldman
Identification, Isolation, and Promoter-Defined Separation of Mitotic Oligodendrocyte Progenitor Cells from the Adult Human Subcortical White Matter
J. Neurosci.,
November 15, 1999;
19(22):
9986 - 9995.
[Abstract]
[Full Text]
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Abstract
Introduction
