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Volume 17, Number 20,
Issue of October 15, 1997
pp. 7850-7859
Copyright ©1997 Society for Neuroscience
Transforming Growth Factor- Null and Senescent Mice Show
Decreased Neural Progenitor Cell Proliferation in the Forebrain
Subependyma
Vincent Tropepe,
Constance
G. Craig,
Cindi M. Morshead, and
Derek van der Kooy
Neurobiology Research Group, Department of Anatomy and Cell
Biology, University of Toronto, Toronto, Ontario M5S 1A8, Canada
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- Summary
- FOOTNOTES
- REFERENCES
ABSTRACT 
The adult mammalian forebrain subependyma contains neural stem
cells and their progeny, the constitutively proliferating progenitor cells. Using bromodeoxyuridine labeling to detect mitotically active
cells, we demonstrate that the endogenous expression of transforming
growth factor- (TGF) is necessary for the full proliferation of
progenitor cells localized to the dorsolateral corner of the
subependyma and the full production of the neuronal progenitors that
migrate to the olfactory bulbs. Proliferation of these progenitor cells
also is diminished with age (in 23- to 25-months-old compared with 2- to 4-months-old mice), likely because of a lengthening of the cell
cycle. Senescence or the absence of endogenous TGF does not
affect the numbers of neural stem cells isolated in
vitro in the presence of epidermal growth factor. These results
suggest that endogenous TGF and the effects of senescence may
regulate the proliferation of progenitor cells in the adult
subependyma, but that the number of neural stem cells is maintained
throughout life.
Key words:
subependyma;
olfactory bulb;
progenitor cell;
stem
cell;
proliferation;
transforming growth factor-;
senescence
INTRODUCTION
The extent of the embryonic germinal
zone is gradually reduced in the perinatal mammalian forebrain, giving
rise in adults to an ependymal monolayer lining the lateral ventricles
and to a two- to three-cell-layer-thick subependyma (Privat and
Leblond, 1972 ; Takahashi et al., 1996a,b). Subependymal cells isolated from the adult mouse brain retain the capacity to differentiate into
neurons or glia in vitro (Lois and Alvarez-Buylla, 1993), whereas in vivo these cells exhibit the ability to migrate
and differentiate into interneurons within the olfactory bulb (Altman, 1969; Lois and Alvarez-Buylla, 1994). Other studies also demonstrate the in vitro isolation of neural stem cells from the adult
forebrain (Reynolds and Weiss, 1992; Gritti et al., 1996), stem cells
similar to those that are the precursors to the progenitor cell
lineages in the embryonic forebrain (Reynolds et al., 1992; Davis and
Temple, 1994). These stem cells exhibit the fundamental stem cell
properties of long-term self-renewal and multipotentiality (Potten and
Loeffler, 1990; Reynolds and Weiss, 1996).
The lineage relationship between stem and progenitor cells in
vivo has been clarified recently. Two subpopulations of the proliferating precursor cells in the adult subependyma have been characterized: constitutively proliferating progenitor cells with a
cell cycle time of ~12.5 hr (Morshead and van der Kooy, 1992) and
their precursors, the relatively quiescent stem cells with a longer
cell cycle time of up to 28 d (Morshead et al., 1994). One of the
progeny of each constitutively proliferating progenitor cell division
will undergo cell death or migrate and differentiate into neurons
within the olfactory bulb, thus maintaining a steady-state mode of cell
division without expanding the population (Morshead and van der Kooy,
1992; Lois and Alvarez-Buylla, 1994).
The endogenous factors that regulate the proliferation of neural stem
and progenitor cells in the adult subependyma are poorly understood.
Two candidates for the endogenous regulation of cell proliferation are
epidermal growth factor (EGF) and transforming growth factor-
(TGF). TGF mRNA has been localized to the adult striatum and
olfactory bulbs, both of which are in close apposition to the forebrain
subependyma (Wilcox and Derynck, 1988; Seroogy et al., 1993).
Conversely, EGF mRNA is localized to relatively ventrocaudal forebrain
regions in the adult, such as the globus pallidus, with apparently
little expression near the subependyma (Fallon et al., 1984; Seroogy et
al., 1995). EGF-receptor expression is detected in both the early
postnatal ventricular zone and the adult subependymal compartments
(Morshead et al., 1994; Seroogy et al., 1994, 1995; Craig et al.,
1996), suggesting that cells in these regions are competent to respond
to EGF and TGF. Intraventricular infusions of either EGF or TGF
in the adult brain can modulate the in vivo proliferation of
subependymal precursor cells by inducing divisions of stem and
progenitor cells (Craig et al., 1996). Thus, on the basis of endogenous
expression patterns and the exogenous ability to modulate
proliferation, these studies indicate that TGF is the best candidate
for endogenously regulating the proliferation of this adult precursor
population.
By using mice with a TGF-targeted null mutation (Luetteke et al.,
1993; Mann et al., 1993), we were able to test directly the role of
endogenous TGF in regulating the in vivo proliferation of
the constitutively proliferating progenitor cells in the adult subependyma and the in vitro clonal proliferation of neural
stem cells. The same experimental approach also enabled us to test whether the proliferation of subependymal neural stem and progenitor cells decreases with age.
MATERIALS AND METHODS
Animals. Male TGF( /) mice
generated on the B6,129/F2 genetic background (STOCK-Tgfa<Tmlr>) and
STOCK controls were obtained from Jackson Laboratory (Bar Harbor, ME).
Male senescent (23-25 months old) mice and young adult controls (2-4
months old) maintained on the SW/COBS genetic background were obtained
from the National Institute of Aging.
Bromodeoxyuridine (BrdU) labeling and detection. Mice were
injected with BrdU (Sigma, St. Louis, MO) (120 mg/kg, i.p., dissolved in 0.007N NaOH in 0.9% NaCl) every 2 hr for 10 hr and killed 0.5 hr
after the last injection. Animals were killed and brains were processed
for immunohistochemistry as described below. Rat monoclonal anti-BrdU
(1:100; Seralab, London, UK) (primary antibody) and biotinylated-donkey
anti-rat (1:200; Jackson ImmunoResearch, West Grove, PA) (secondary
antibody) with streptavidin-Texas Red or streptavidin-CY3 (1:100;
Sigma) were used for BrdU detection.
Immunohistochemistry. Animals were killed by anesthetic
overdose and perfused transcardially with 4% paraformaldehyde and 0.4% picric acid in 0.16 M phosphate buffer, pH 6.9 (Zamboni and de Martino, 1967). Brains were post-fixed in the perfusing
solution for 90 min at 4°C and then cryoprotected for at least 24 hr
in 10% sucrose in 0.1 M PBS, pH 7.2. Serial 14 µm
coronal cryosections ( 19°C) of mouse forebrain were mounted
directly onto gelatin-coated slides. After initial treatment with 1 M HCl for 30 min at 65°C to denature cellular DNA,
sections were washed three times (10 min each) with washing solution
(10 mM PBS). Sections were incubated for 24 hr (4°C) in
primary antibody diluted in washing solution containing 0.3% Triton
X-100 and 0.01% sodium azide. After incubation in the primary
antibody, sections were washed (as above) and incubated with the
biotinylated secondary antibody for 2 hr at 37°C followed by
incubation with tertiary streptavidin-Texas Red or streptavidin-CY3 for 40 min at 37°C. Sections were washed three times (5 min each), coverslipped with Immu-mount (Shandon-Lipshaw, Pittsburgh, PA), and
examined under a fluorescent microscope (Nikon). Specificity of
immunostaining was confirmed by the absence of detectable fluorescence in sections processed after omitting the primary antibody.
Nissl staining. Cell density counts were ascertained by
taking three to four coronal sections (that were evenly spaced
throughout the counted area) per brain from three to four mice per
experimental group and their appropriate controls and staining for
Nissl substance using cresyl violet. The numbers of cells per unit area
were counted from sampled areas in the medial wall, lateral wall, and
dorsolateral corner of the adult subependyma. These same sections were
also used for camera lucida (Nikon) drawings to determine the area of
the subependyma from the same sampled, evenly spaced sections.
Brain dissection and isolation of neurospheres in vitro. The
protocol used to generate neurospheres in vitro was adopted
from Reynolds and Weiss (1992). Briefly, mice were killed via cervical dislocation, and their brains were excised under sterile conditions. Medial and lateral portions of the lateral ventricle subependyma were
dissected from both hemispheres, pooled together, and subsequently cut
into 1 mm2 fragments in oxygenated artificial
cerebrospinal fluid (aCSF) that contained 124 mM NaCl, 5 mM KCl, 1.3 mM MgCl2, 2 mM CaCl2, 26 mM
NaHCO3, and 10 mM D-glucose.
The tissue from each brain was transferred to a spinner flask (Bellco
Glass) containing aCSF (as above), but modified to contain high
Mg2+ (3.2 mM MgCl2)
and low Ca2+ (0.1 mM
CaCl2) concentrations, and containing 1.33 mg/ml
trypsin (Sigma), 0.67 mg/ml hyaluronidase (Sigma), and 0.2 mg/ml
kynurenic acid (Sigma) to dissociate tissue, and oxygenated at 30°C
for 90 min. Tissue was then transferred to serum-free media containing 0.7 mg/ml trypsin inhibitor (Boehringer Mannheim, Indianapolis, IN) and
triturated with a fire-polished Pasteur pipette. Cells were cultured in
chemically defined serum-free media containing DMEM/F12 (1:1) (Life
Technologies, Gaithersburg, MD), 5 mM HEPES buffer, 0.6%
glucose, 3 mM NaHCO3, 2 mM
glutamine, 25 µg/ml insulin, 100 µg/ml transferrin, 20 nM progesterone, 60 µM putrescine, and 30 nM sodium selenite in the presence of EGF (20 ng/ml;
purified from mouse submaxillary gland; Upstate Biotechnology, Lake
Placid, NY) in 35-mm-diameter Nunclon culture dishes. After 12-14 d
in vitro, the numbers of spheres generated in the culture
wells (12 wells/subependyma) were counted, and the total number of
spheres per subependyma was averaged over the number of brains. Data
were collected from three independent mouse culture preparations in each group of each experiment.
Olfactory bulb cell counts. Mice were injected
intraperitoneally (as described previously) every 2 hr for five
injections. The animals were maintained on a 12 hr light/dark cycle
with food and water ad libitum and were allowed to survive
for 31 d. The animals were then killed and the tissue was
processed for immunocytochemistry as described above. Sampled, evenly
spaced sections through the olfactory bulb (starting from the rostral
tip of a defined subependymal layer within the center of the internal
granule layer and terminating caudally at the appearance of the
accessory olfactory nuclei) were included in the analyses.
Estimating a change in cell cycle time. Animals received one
intraperitoneal injection (0.15 ml) of BrdU (Sigma) (18 mg/ml dissolved
in 0.007N NaOH) at time designated t = 0. At 12.5 hr (t = 12.5) after the initial BrdU injection, mice
received one intraperitoneal injection (0.15 ml) of tritiated thymidine
(3H-thy; specific activity 50 Ci/mM). Animals
were killed 1 hr after the last injection with an anesthetic overdose.
The mice were then transcardially perfused with fixative (as above),
and the brains were removed and post-fixed in perfusing solution for 90 min at 4°C followed by cryoprotection in 10% sucrose at 4°C for at
least 24 hr. Forebrain coronal cryosections were cut at 6 µm, mounted
on gelatin-coated slides, and processed for BrdU and 3H-thy
as follows. Sections were incubated in 1.0 M HCl at 65°C for 30 min and subsequently washed in a buffer (10 mM PBS)
three times (10 min each). Sections were then incubated in 1:100
anti-BrdU (Sera-Lab, Sussex, UK) (diluted in wash buffer) for 24 hr at
4°C. Sections were then washed three times (10 min each) and
incubated in biotinylated donkey anti-rat antibody (Jackson Laboratory) at 1:100 dilution (in wash buffer) for 1 hr at room temperature. After
sections were washed, bound biotinylated secondary antibody was
detected using avidin-bound peroxidase (10 µl/ml; Vector Kit, Vector
Laboratories, Burlingame, CA) at room temperature for 30 min, washed,
and incubated with diaminobenzidine (1 mg/ml; Vector Kit) for 2-10 min
at room temperature in the dark. Subsequently, sections were defatted
in xylene and dehydrated in increasing concentrations of alcohol and
processed for autoradiography by dipping the slides in liquid emulsion
(Kodak NTB-2 nuclear track emulsion). The sections were exposed for 7 weeks, after which time they were developed with Kodak D-19 developer.
The total numbers of BrdU+ cells within the entire
extent of the subependyma, and within the dorsolateral corner subregion
alone, were counted in sections caudal to the genu of the corpus
callosum and rostral to the crossing of the anterior commissure. The
numbers of
BrdU+/3H-thy+ cells
were also counted within the same sections. The average numbers of
double-labeled cells as percentages of the total numbers of cells
proliferating at t = 0 were calculated.
Cell counts. For all histological forebrain and olfactory
bulb sections, cell numbers were estimated by quantifying the number of
cell profiles/section at constant intervals and correcting for nuclear
size and section thickness to obtain an unbiased number of cell
profiles (Abercrombie, 1946). In light of the concerns regarding the
use of assumption-based methods to accurately represent cell number
(Coggeshall and Lekan, 1996), we analyzed our olfactory bulb migration
data set for senescent mice by comparing the assumption-based method
and the optical disector method to determine whether the final
estimates of cell number were significantly different. There were no
significant differences in our estimates of cell number comparing the
Abercrombie and optical disector methods in either the 2- to
4-months-old (t6 = 0.55; p > 0.05) or 23- to 25-months-old (t6 = 0.34;
p > 0.05) groups. Therefore, we refer to our unbiased estimates of cell profiles as cell numbers. The estimates of
BrdU+ cell numbers (within the anatomical region of
the olfactory bulb defined above) that were larger in the 2- to
4-months-old mice than in the 23- to 25-months-old mice showed similar
significant differences using the Abercrombie
(t6 = 5.09; p < 0.05) and
optical disector (t6 = 6.44; p < 0.05) methods.
RESULTS
Division of constitutively proliferating progenitor cells is
attenuated throughout the subependyma in senescent mice, but only
attenuated in the dorsolateral corner in TGF(/)
mice
Constitutively proliferating progenitor cells are present
throughout the entire forebrain subependymal region. The rostral, dorsolateral corner of the subependyma may be enriched for neuronal progenitor cells that migrate to the olfactory bulbs where they undergo
differentiation (Altman, 1969; Luskin, 1993; Lois and Alvarez-Buylla,
1994). The localization of olfactory bulb neuronal progenitors to the
dorsolateral corner of the lateral ventricle suggests that this region
of the subependyma may be functionally distinct from the remaining
nondorsolateral subependyma. To determine the role of TGF and the
effects of senescence on the proliferation of constitutively
proliferating progenitor cells in vivo, we analyzed progenitor cell proliferation separately in the dorsolateral corner and
in the remaining nondorsolateral subependyma. This analysis allowed us
to test whether cells in distinct regions of the subependyma are
differentially affected by TGF(/) or senescence. We
used BrdU, a thymidine analog incorporated into the DNA of these cells
in the S-phase of their cell cycle (Nowakowski et al., 1989), to
quantify cell proliferation of these cells in adult
TGF(/) and senescent mice (Fig.
1).
Fig. 1.
Decreased subependymal cell proliferation in
TGF(/) mice in vivo.
A, Schematic diagram representing a coronal section
through the adult mouse forebrain lateral ventricle subependyma
(gray shaded area around lv).
Boxed area indicates the region of the dorsolateral
corner pictured in B and C. B,
C, Fluorescent photomicrograph of a coronal section through the
dorsolateral corner of the subependyma of the adult forebrain lateral
ventricle in (B) a control B6129/F2 mouse and
(C) a TGF(/) mouse. Animals
received 10 hr of BrdU injections to label the entire constitutively
proliferating population. cc, Corpus callosum; lv, lateral ventricle; se, subependyma;
str, striatum. Scale bar, 80 µm.
[View Larger Version of this Image (34K GIF file)]
Attenuated proliferation of constitutively proliferating progenitor
cells in the dorsolateral corner of the adult subependyma was observed
in TGF(/) (Fig.
2A) and senescent mice
(Fig. 2B). The numbers of BrdU+
constitutively proliferating progenitor cells were significantly decreased by 43% in TGF(/)
(t6 = 6.8; p < 0.05) and by
47% in senescent (t6 = 6.6; p < 0.05) mice when compared with their control groups. To compare the
effects of TGF deficiency on the proliferation of the remaining
population of constitutively proliferating progenitor cells, we
quantified the number of BrdU+ cells localized to
the remaining nondorsolateral subependyma. The numbers of
BrdU+ cells in the nondorsolateral subependyma of
adult TGF(/) mice were not significantly different
from their strain-matched controls (t6 = 1.4;
p > 0.05) and suggest that these cells proliferate independently of normal endogenous TGF expression (Fig.
2C). Senescent mice (Fig. 2D), however,
had 64% fewer constitutively proliferating progenitor cells throughout
the nondorsolateral subependyma than their appropriate controls
(t8 = 10.8; p < 0.05).
Fig. 2.
Attenuated proliferation in the forebrain
subependyma of TGF-deficient and senescent mice. The number of
proliferating (BrdU+) cells were counted in the
subependymal region of TGF(/) and 23- to
25-months-old mice. The mean (± SEM) of the total number of
BrdU+ cells in the dorsolateral corner of the
subependyma (A, B) and the mean (± SEM) of the total
number of BrdU+ cells throughout the nondorsolateral
extent of the subependyma (C, D) were estimated on the
basis of counts between the rostral tip of the genu of the corpus
callosum and the crossing of the anterior commissure from (A,
C) every seventh section in this region per animal, from young
adult TGF(/) (n = 4) mice and
B6129/F2 (n = 4) controls, and from (B,
D) every seventh section in this region per animal, from 23- to
25-months-old (n = 5) mice and 2- to 4-months-old
(n = 5) controls. * Significantly different from
control (p < 0.05).
[View Larger Version of this Image (28K GIF file)]
To examine the possibility that the differences observed in the
quantified numbers of BrdU+ cells were caused by
other histological changes, coronal forebrain sections from both groups
and their appropriate controls were stained for Nissl substance using
cresyl violet to determine the density of subependymal cells. The
cellular density per unit area in the dorsolateral corner of the
subependyma was not significantly altered in TGF(/)
(t6 = 0.82; p > 0.05) or
senescent (t4 = 2.54; p > 0.05)
mice compared with their controls. Similarly, no differences in cell density were observed in the lateral and medial walls of the
subependyma for these two experimental groups compared with their
appropriate controls. These same sections were also used for camera
lucida tracings to determine whether there were any changes in the area of the subependyma. No changes in the entire area of the forebrain subependyma were observed in the TGF(/)
(t6 = 1.81; p > 0.05) and
senescent (t4 = 0.18; p > 0.05)
mice compared with their controls. Thus, the decrease in the numbers of
BrdU+ cells is likely the result of reduced
proliferation. In both experimental (mutant vs old) groups and their
appropriate control groups we observed baseline differences in
proliferation attributable to mouse strain (B6,129/F2 vs SW/COBS).
These differences were consistent across all experiments throughout the
results. Background strain differences may correspond to variations in
endogenous levels of some factor(s) involved in regulating the
proliferation of the constitutively proliferating progenitor cell
population.
The numbers of subependymal neuronal progenitor cells that have
migrated to the olfactory bulbs are decreased in
TGF(/) and senescent mice
To determine whether the decreased numbers of
BrdU+ cells in the dorsolateral corner of the
subependyma in TGF(/) and senescent mice are also
reflected in an attenuation in the numbers of neuronal progenitor cells
that have migrated to the olfactory bulbs, animals were injected with
BrdU and allowed to survive for 31 d after injection, a sufficient
time to allow for the migration of labeled neuronal progenitor cells to
the olfactory bulbs (Lois and Alvarez-Buylla, 1994; Doetsch and
Alvarez-Buylla, 1996). The numbers of BrdU+ cells
within the olfactory bulbs were then assayed. The total number of
BrdU+ olfactory bulb cells was significantly
decreased by 37% in TGF(/) mice and by 70% in
senescent mice when compared with their appropriate control groups
(Fig. 3). There were significantly fewer
numbers of BrdU+ cells in TGF(/)
(t8 = 3.40; p < 0.05) and
senescent (t6 = 5.09; p < 0.05)
mice compared with strain-matched controls. The data indicate that the
absence of endogenous TGF in the adult forebrain and the effects of
senescence cause a decrease in the proliferation of neuronal
progenitors that have migrated rostrally from primarily the
dorsolateral corner of the subependyma to the olfactory bulbs. Furthermore, the significantly greater percentage reduction in the
numbers of neuronal progenitor cells that migrated to the olfactory
bulb in the senescent mice compared with TGF(/) mice
(t7 = 3.62, p < 0.05) indicates
that the effects of senescence on this population are not caused
exclusively by TGF deficiency.
Fig. 3.
Numbers of BrdU+ cells that
migrated from the dorsolateral corner of the subependyma to the
olfactory bulbs. The numbers of olfactory bulb BrdU+
cells 31 d after BrdU injection in (A)
B6129/F2 control and TGF(/) mice and
(B) 2- to 4-months-old control and 23- to
25-months-old mice. Counts are the mean ± SEM of the total number
of BrdU+ cells (from every tenth section in this
region per animal) from five separate mice in the
TGF(/) and control groups, and the total number of
BrdU+ cells (from every eighth section in this
region per animal) from four separate mice in the senescent and control
groups. * Significantly different from control
(p < 0.05).
[View Larger Version of this Image (12K GIF file)]
Interestingly, we observed a reduction in the numbers of constitutively
proliferating progenitor cells in the dorsolateral corner of the
subependyma and a maintenance of the numbers of constitutively
proliferating progenitor cells throughout the remaining nondorsolateral
subependyma in waved-1 homozygous mice as well (our unpublished
observations). Furthermore, the numbers of neuronal progenitor cells
that migrated to the olfactory bulbs from primarily the rostral,
dorsolateral subependyma were diminished in these mice. Waved-1 is a
TGF hypomorphic mutation that is allelic with the
TGF(/) mutation (Luetteke et al., 1993). Thus, these
observations indicate that the proliferation of this cell population is
very sensitive to the endogenous levels of TGF because both the
complete absence of TGF (TGF(/) mice) and
decreased levels of TGF (waved-1 mice) significantly attenuate the
proliferation of neural progenitor cells in the adult dorsolateral
subependyma.
The labeling intensity of BrdU+ cells in the
olfactory bulb after a 31 d survival period was decreased compared
with the labeling intensity of BrdU+ cells in the
subependyma after a 30 min survival period. A potential concern with
long-term survival analyses is the dilution of the BrdU label in
dividing cells; however, given that both the senescent and young adult
control mice received identical labeling regimens, and because the cell
cycle time in the senescent mice is increased compared with that in
their young adult controls (see below), the decrease in the numbers of
labeled cells in the olfactory bulb of senescent animals (compared with
their controls) after 31 d cannot be caused by greater dilution of
the label in the senescent mice. Indeed, the actual decrease in the
olfactory bulb may be underestimated.
Senescence causes a lengthening of the cell cycle in constitutively
proliferating progenitor cells
BrdU and 3H-thy double-labeling allowed assessment of
whether a change in cell cycle time could account for the decrease in the number of constitutively proliferating progenitor cells in vivo in the senescent subependyma (which showed a larger overall decrease than the TGF(/) subependyma). Mice were
injected with a pulse of BrdU at time t = 0 and a pulse
of 3H-thy at t = 12.5 hr to label
subependymal cells in two consecutive S-phases of their cell cycles.
Because the total cell cycle time for constitutively proliferating
progenitor cells has been estimated as ~12.5 hr (Morshead and van der
Kooy, 1992), only those cells that were originally labeled with BrdU at
t = 0 and that were reentering S-phase at the time of
the 3H-thy pulse (t = 12.5) would
incorporate the second marker into their DNA and thus become
double-labeled.
In young adult mice (2-4 months old), 56% of the BrdU-labeled
constitutively proliferating progenitor cells were double-labeled for
3H-thy around the nondorsolateral subependyma, and 58%
were double-labeled in the dorsolateral corner of the subependyma (Fig.
4). These two percentages were not
significantly different (t2 = 2.1;
p > 0.05) in the young adult mice, indicating that the
cell cycle times of the constitutively proliferating progenitor cells
are similar throughout the entire subependyma. Given that 40-45% of the cells that were proliferating at t = 0 were not
reentering S-phase at t = 12.5 (not
double-labeled), we suggest that roughly half of the progeny of the
BrdU+ cells adopted an alternative, nonproliferative
fate. This steady-state mode of proliferation is required to maintain
the size of the subependyma throughout adult life. Some of the neuronal
progenitors in the dorsolateral corner become postmitotic and migrate
rostrally to the olfactory bulbs (Lois and Alvarez-Buylla, 1993, 1994), and many of the postmitotic progeny of the constitutively proliferating progenitor cells undergo cell death (Morshead and van der Kooy, 1992).
Fig. 4.
Estimate of change in cell cycle time in young
adult and senescent mice. The average number (±SEM) of cells
double-labeled as a percentage of total numbers of cells proliferating
at t = 0 were obtained from four hemisections from
each of two 2- to 4-months-old mice and two hemisections from each of
three 23- to 25-months-old mice. * Significantly different from control (p < 0.05).
[View Larger Version of this Image (14K GIF file)]
In senescent mice (23-25 months old), only 30% of the dividing cells
in the dorsolateral corner of the subependyma and throughout the
remaining subependyma were still proliferating at t = 12.5 (double-labeled with 3H-thy) (Fig. 4). This 30% rate
in senescent mice is significantly less than the almost 60%
double-labeled cells in the 2- to 4-months-old controls at 12.5 hr
(t4 = 4.4; p < 0.05). Again, no
significant difference in the percentage of double-labeled cells was
observed between the dorsolateral corner and the rest of the
subependymal region within the 23- to 25-months-old group
(t4 = 0; p > 0.05). Thus, there
is a ~50% decrease in the relative numbers of constitutively proliferating progenitor cells dividing with a cell cycle time of 12.5 hr in the subependyma of senescent mice compared with young adult
controls. Given that, in addition to a change in cell cycle length,
senescence produced a decrease in the numbers of proliferating cells
labeled with continuous BrdU over 10 hr and that the cell density is
maintained in the subependyma (Nissl staining), the simplest
interpretation of the data is that there is a longer average cell cycle
time among the constitutively proliferating progenitor cells.
Neural stem cell proliferation in vitro is unaltered in
TGF(/) and senescent mice
The decrease in the number of constitutively proliferating
progenitor cells in the subependyma of TGF(/) and
senescent mice could be a consequence of decreased proliferation by the
neural stem cells, which are the lineage precursors to the progenitor
cells (Morshead et al., 1994) and have been shown to proliferate
in vitro to form clonal aggregates (neurospheres) in the
presence of EGF (Reynolds and Weiss, 1992). In tissue culture preparations we observed no significant differences in the numbers of
neurospheres clonally generated in EGF in vitro from neural stem cells in either TGF(/)
(t4 = 0.32; p > 0.05) or
senescent (t4 = 0.01; p > 0.05)
mice compared with their strain-matched controls (Fig.
5). Furthermore, the sizes of
neurospheres generated in vitro did not change in TGF(/) or senescent mice compared with their
controls (data not shown), suggesting that the progeny of stem cells
in vitro seem to be capable of responding to a mitogenic
signal through a normally functioning EGF receptor. It remains formally
possible that the neural stem cells isolated from the
TGF(/) mice have altered their responsiveness
exclusively to TGF and not to EGF, and that this prevents us from
detecting an actual change in the neural stem cells in
TGF(/) or senescent mice when they are assessed
in vitro using EGF. However, the similarity between EGF and
TGF binding to the EGF-receptor (Massague, 1983; Marquardt et al.,
1984) and the ability of both of these ligands to equally induce the
proliferation of neural stem cells to generate neurospheres in
vitro (Reynolds and Weiss, 1992) and to expand the subependymal
precursor population in vivo (Craig et al., 1996) provide
evidence suggesting that there is no functional distinction in the
ability of these two ligands to induce neural stem cell
proliferation.
Fig. 5.
Clonal generation of neurospheres from
subependymal neural stem cells in vitro is not affected
in TGF-deficient and senescent mice. The number of neurospheres
generated per brain from (A) adult
TGF(/) mice and B6129/F2 controls and
(B) 23- to 25-months-old and 2- to 4-months-old
controls after 12-14 d in vitro. Tissue from the medial
and lateral (including the dorsolateral corner) aspects of the
subependyma was dissected from both hemispheres, pooled together, and
cultured in serum-free media in the presence of 20 ng/ml EGF. Data
represent the mean ± SEM for independent culture preparations
from three mice in each group.
[View Larger Version of this Image (15K GIF file)]
We observed baseline differences attributable to mouse strain (B6,
129/F2 vs SW/COBS) in the numbers of neurospheres generated in both
experimental (mutant vs old) groups and their appropriate controls.
Strain differences also were observed in experiments assaying the
numbers of constitutively proliferating progenitor cells in the
dorsolateral corner and nondorsolateral subependyma and the numbers of
neuronal progenitors migrating to the olfactory bulb. The numbers of
BrdU-labeled cells in the B6129/F2 strain were consistently greater
than the numbers of BrdU-labeled cells in the SW/COBS strain across all
experiments assaying the constitutively proliferating progenitor
population. The opposite was true, however, for the analysis of the
numbers of neural stem cells isolated in vitro between these
two strains (more were isolated in the SW/COBS strain). These results
suggest that distinct endogenous mechanisms can control the
constitutively proliferating progenitor cell population and the
neural stem cell population, and indeed that these two steps in the
neural precursor lineage can be regulated independently.
DISCUSSION
TGF regulates the proliferation of a specific subpopulation of
constitutively proliferating progenitor cells in the adult
subependyma
The results of the present study demonstrate that TGF
expression is required for the proliferation of constitutively
proliferating progenitor cells localized to the dorsolateral corner of
the adult subependyma but not the nondorsolateral subependyma. The
proliferation of neuronal progenitor cells in the dorsolateral corner
that migrate rostrally to the olfactory bulb (Lois and Alvarez-Buylla,
1994) also is dependent on normal endogenous TGF expression. Thus, the dorsolateral corner of the subependyma may contain most of the
neuronal progenitors that migrate to the olfactory bulb. Perhaps the
simplest hypothesis to explain the difference in TGF-dependent proliferation is that the same constitutively proliferating progenitor cell population responds differently depending on the growth factor expression in different regions of the adult subependyma (Fig. 6). TGF-dependent proliferation of
constitutively proliferating progenitors may be contingent on their
location in the dorsolateral corner. The relatively restricted domain
of normal TGF expression in rostral, dorsal regions of the forebrain
(Wilcox and Derynck, 1988; Seroogy et al., 1993) may elicit a
proliferative response only in those rostral, dorsolateral subependymal
cells destined to migrate to the olfactory bulbs. The lack of a
proliferation deficit in the constitutively proliferating progenitors
throughout the remaining subependyma in the TGF null mice suggests
that other growth factors expressed in the nondorsolateral subependyma (ventrolateral and medial), especially EGF expression in more caudal
and ventral regions such as the globus pallidus (Fallon et al., 1984;
Seroogy et al., 1995), may regulate the proliferation of cells in this
spatially distinct part of the forebrain subependyma.
Fig. 6.
Model representing the lineage relationships of
neural stem cells and constitutively proliferating (CP)
progenitor cells. A, Neural stem cells localized to the
dorsolateral corner of the adult forebrain subependyma give rise to CP
progenitor cells that proliferate to give rise to neuronal progenitor
cells that are destined to migrate to the olfactory bulbs where they
differentiate into mature neurons. Some cells in the dorsolateral
corner also may remain localized to the dorsolateral corner of the
subependyma where they continue to proliferate and subsequently undergo
cell death, as do the cells in the rest of the subependyma
(B). B, Neural stem cells
throughout the rest of the subependyma give rise to CP progenitor cells
that proliferate to give rise to one more CP cell and one cell destined
to die. In both A and B the CP cells
proliferate for <1 month before they are replenished by a neural stem
cell division.
[View Larger Version of this Image (28K GIF file)]
It is unlikely that the TGF-dependent proliferation of cells only in
the dorsolateral corner of the subependyma is indicative of an
intrinsically distinct subpopulation of constitutively proliferating progenitor cells. First, intraventricular infusion of TGF in the
adult brain causes the proliferation and migration of constitutively proliferating progenitor cells throughout the entire subependymal region (Craig et al., 1996). Thus, progenitor cells localized to the
ventrolateral and medial subependyma (along its entire rostral-caudal
extent) that do not normally migrate into adjacent brain parenchyma
in vivo can be induced to migrate with exogenous TGF.
Neural stem cells also proliferate in vivo in response to infused TGF because the numbers of neurospheres subsequently isolated in the presence of EGF in vitro were augmented
(Craig et al., 1996). Therefore, the expansion of the constitutively proliferating progenitor cell population in vivo is likely
caused by the proliferation of both the progenitor and stem cell
populations, which are capable of responding to EGF-receptor ligands.
Second, heterotopic transplantation of progenitor cells originating at different rostrocaudal levels of the adult dorsolateral subependyma can
migrate to the olfactory bulb and differentiate into neurons (Doetsch
and Alvarez-Buylla, 1996), although in vivo the adult rostral dorsolateral corner of the subependyma may give rise to more
olfactory bulb progenitors than the caudal dorsolateral corner (C. M. Morshead, C. G. Craig, and D. van der Kooy, unpublished observations). Finally, neuronal progenitor cells elsewhere in the
adult brain can respond differentially to environment-specific cues.
Adult rat hippocampal progenitor cells heterotopically transplanted to
the rostral migratory pathway of olfactory bulb interneuron progenitors
have been shown to migrate rostrally and to differentiate into neurons,
some of which expressed tyrosine hydroxylase, an enzyme specific to
olfactory bulb periglomerular dopaminergic neurons but not present in
the hippocampus (Suhonen et al., 1996). The results of these studies
and the present data describing the TGF-dependent proliferation of
constitutively proliferating progenitor cells in the dorsolateral
corner strongly support the hypothesis that there may be a single
constitutively proliferating progenitor cell population, and that when
members of this population are localized to the dorsolateral corner of
the subependyma, they are then poised to divide in response to the
relatively localized expression of TGF to give rise to olfactory
bulb neuronal progenitors.
The results also allow us to dissociate proliferation and migration
with the dorsolateral constitutively proliferating population that
gives rise to new adult olfactory bulb neurons. The olfactory bulb
interneuron progenitor cells that are generated in the adult rostral,
dorsolateral subependyma migrate along a distinct rostral migratory
path to the olfactory bulb where they undergo differentiation (Lois and
Alvarez-Buylla, 1994). Ultrastructural analyses demonstrate that the
cells migrating from the lateral ventricle subependyma to the olfactory
bulb (rostral migratory stream) are  -tubulin-positive and polysialic
acid-neural cell adhesion molecule (PSA-NCAM)-positive neuroblasts
(Type A cells) that are ensheathed by nonmigrating, GFAP-positive (Type
B cells) astrocytes (Doetsch et al., 1997). Recent evidence suggests
that the chained migration of neuronal progenitors on top of one
another may be the mechanism by which the progeny of the constitutively
proliferating progenitors migrate tangentially to the olfactory bulbs,
and that PSA-NCAM is the critical factor that regulates the
intercellular adhesion in this process (Tomasiewicz et al., 1993;
Cremer et al., 1994; Rousselot et al., 1995; Hu et al., 1996; Lois et
al., 1996). In the present study, the number of proliferating neuronal
progenitors that migrated rostrally from the dorsolateral corner of the
subependyma to the olfactory bulbs was diminished in the
TGF(/) animals. This proliferation deficit seems to
be a mechanistically and spatially distinct effect from the selective
migratory deficit of neuronal progenitors to the olfactory bulbs in
NCAM(/) animals (Tomasiewicz et al., 1993;
Cremer et al., 1994). Subependymal progenitor cells in the
NCAM(/) mice accumulate in situ,
causing an expansion of the subependymal zone, which suggests that
proliferation of these progenitor cells is unaffected. Conversely,
subependymal progenitor cells in the TGF(/) mice
show an intrinsic decrease in proliferation (a decrease in BrdU
incorporation) with some preservation of cell migration, because the
remaining progenitors in the dorsolateral corner give rise to cells
that migrate from the subependyma to the olfactory bulb 31 d after
BrdU administration. Furthermore, the apparently unaltered size of the
olfactory bulbs of TGF(/) animals suggests again
that migration is spared and that the defect is selective in
diminishing proliferation of constitutively proliferating progenitors
within the subependyma. Thus, these data provide a clear distinction
for the role of TGF as a mitogen for constitutively proliferating
progenitor proliferation versus the role of PSA-NCAM as a critical
intercellular adhesion molecule for neuronal progenitor migration.
Proliferation of constitutively proliferating progenitor cells in
the subependyma is diminished in senescent mice
The present study demonstrates that proliferation of
constitutively proliferating progenitor cells is decreased in the
dorsolateral corner and throughout the remaining subependyma by
~50-60% in senescent compared with young adult mice. Furthermore,
the number of neuronal progenitors that migrated to the olfactory bulbs
is decreased by ~70% in senescent mice. Thus, although proliferation of these progenitor cells persists in the adult mammalian subependyma, this proliferation diminishes with age. These results are consistent with previous studies demonstrating that in regions of the adult brain
with persistent neurogenesis, such as the olfactory bulb and the
dentate gyrus of the hippocampus, there is increased neuronal loss with
age (Kaplan, 1985), and that proliferation in the subependyma diminishes with age (Hopewell, 1971). Although these studies reveal that the numbers of cells in these regions were decreased, evidence for
diminished neurogenesis remained inconclusive (Kaplan, 1985). The
diminished numbers of constitutively proliferating progenitor cells in
the dorsolateral corner of the subependyma roughly correlates with the
reduction in the numbers of neuronal progenitor cells that migrate to
the olfactory bulb and therefore is consistent with the idea that
neurogenesis in the forebrain subependyma is attenuated in senescent
mice.
The similarity between the reductions of constitutively proliferating
progenitor cell proliferation in the dorsolateral corner of the
subependyma in TGF-deficient and senescent mice suggests that the
same mechanism (decreased TGF levels) may underlie the diminished
proliferation in the dorsolateral corner in both groups of mice. It
remains to be determined, however, whether the levels of TGF
expression in the senescent forebrain are decreased. Furthermore, decreased levels of TGF in the senescent forebrain alone are insufficient to account for the greater reduction in the numbers of
neuronal progenitor cells that migrated to the olfactory bulb in
senescent mice when compared with the TGF(/) mice.
This further supports the idea that proliferation of the constitutively
proliferating progenitor cell lineage in the adult subependyma may be
regulated by multiple, spatially distinct factors.
Recently, Kuhn et al. (1996) demonstrated that neurogenesis in the
dentate gyrus of senescent rats also is diminished; however, in control
experiments Kuhn et al. (1996) reported no change in the proliferation
of subependymal progenitor cells in the senescent rat. It is possible
that species differences (mouse vs rat), differences in the regions of
the subependyma analyzed, and the lack of a stereological correction
factor applied to their cell counts (40 µm thick sections) may have
contributed to the discrepancy between studies. Nonetheless, our
present results indicate that in the adult mouse forebrain subependyma,
constitutively proliferating progenitor cells and committed neuronal
progenitor cells have a limited proliferative potential in
vivo.
Almost 60% of the constitutively proliferating progenitor cells in the
2- to 4-months-old control mice reentered S-phase after 12.5 hr (the
time of one cell cycle) and thus were double-labeled by BrdU and
3H-thy injections separated by 12.5 hr. One fate of the
nondouble-labeled progeny (or at least a proportion of the remaining
cells that are localized to the dorsolateral corner of the subependyma)
may have been rostral migration to the olfactory bulb; however, the fate of most of the nondouble-labeled progeny of constitutively proliferating progenitor cells throughout the remaining subependyma (and indeed of some of the progeny in the rostral, dorsolateral corner
as well) may have been cell death (Fig. 6). In senescent mice, the
percentage of subependymal cells double-labeled at t = 12.5 hr was ~30% (down from 60% in the 2- to 4-months-old
controls), indicating that there is a change in cell cycle time. Given
that in addition to a change in cell cycle length senescence produced a
decrease in the numbers of proliferating cells labeled with continuous
BrdU over 10 hr and yet the cell density was maintained in the
subependyma, the simplest interpretation of the data is that there is a
longer average cell cycle time among the constitutively proliferating
progenitor cells in senescent mice. Assuming a steady-state mode of
division, a longer cell cycle time, and a concurrent maintenance of
cell density throughout the entire senescent subependyma, then cell
death must be decreased (cells live longer) in proportion to the
increase in cell cycle time. An alternative interpretation is that
there is a shortening of the cell cycle and an increase in the amount
of cell death. Although consistent with the observed change in the
numbers of double-labeled cells and maintenance of cell density, this
interpretation seems less likely, because under continuous
BrdU-labeling conditions massive amounts of cell death in a very short
period of time would be necessary to account for the observed reduction
in the numbers of proliferating cells. Cumulative S-phase labeling or
percentage labeled mitoses analyses of cell cycle time in the senescent
mice and young adult control mice will be necessary to confirm that the
estimated change in cell cycle truly reflects an increased cell cycle
time. Whether this putative lengthening in cell cycle time is
associated with changes in extrinsic growth factor regulation of cell
division also remains to be determined.
Neural stem cells are unaffected in TGF(/) and
senescent mice
The ability of subependymal neural stem cells to proliferate
in vitro in the presence of EGF is unaltered in
TGF(/) and senescent mice. This is the first
demonstration that the number of neural stem cells is maintained late
in mammalian life. Thus, neural stem cells are present from the early
stages (as early as E14) of neural development (Reynolds et al., 1992;
Vescovi et al., 1993) to senescence (present results). This feature
(long-term self-renewal) is a fundamental characteristic of stem cells
(Potten and Loeffler, 1990; Weiss et al., 1996). The generation of a
single neurosphere from the clonal proliferation of a single neural
stem cell (Reynolds and Weiss, 1992, 1996) provided us with a
quantitative assay for determining the numbers of neural stem cells
that are capable of proliferating in response to EGF in
vitro. The unaltered ability of adult neural stem cells from
TGF(/) mice to generate neurospheres in
vitro also suggests that other growth factors, such as EGF or
basic fibroblast growth factor, can regulate neural stem cell
proliferation during in vivo development. Indeed, stem cells
do not depend on the endogenous expression of TGF during
development, because the capacity of neural stem cells to respond to
EGF (the defining member of the EGF-receptor ligand family) is
conserved in TGF(/) mice.
Summary
This study demonstrates that in the rostral, dorsolateral corner
of the adult forebrain subependyma, TGF is necessary for regulating
the proliferation of constitutively proliferating progenitors that give
rise to neuronal progenitors migrating to the olfactory bulbs. We
propose that the constitutively proliferating progenitor cells
throughout the forebrain subependyma are capable of proliferating in
response to different endogenous growth factors (e.g., EGF-receptor signaling ligands) that are localized in spatially distinct domains, and that the neural stem cell (also responsive to EGF-receptor ligands)
is the lineage precursor to the entire constitutively proliferating
progenitor population (Fig. 6). The survival and proliferation of the
forebrain neural stem cell itself does not depend on TGF signaling
specifically, and these neural stem cells remain undiminished in the
adult forebrain subependyma throughout life, even in senescent animals.
The postmitotic progeny of constitutively proliferating progenitors
throughout the nondorsolateral forebrain subependyma (and indeed of
some in the dorsolateral corner as well) that do not respond to the
endogenous TGF signal undergo cell death and thus maintain a
steady-state mode of division with no expansion of the overall
subependymal population itself. The diminished proliferation of
constitutively proliferating progenitor cells throughout the
subependyma in senescent mice likely reflects a lengthening in the cell
cycle time and may be a consequence of age-related changes in the
mechanisms that regulate the proliferation of this cell population
throughout the adult forebrain.
FOOTNOTES
Received May 14, 1997; revised July 23, 1997; accepted August 5, 1997.
This work was supported by the Medical Research Council of Canada and
the Canadian Neuroscience Network. We thank Esther Galindo for
excellent technical assistance.
Correspondence should be addressed to Vincent Tropepe, Neurobiology
Research Group, Department of Anatomy and Cell Biology, University of
Toronto, Medical Sciences Building Room 1105, 1 King's College Circle,
Toronto, Ontario M5S 1A8, Canada.
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