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The Journal of Neuroscience, August 15, 2000, 20(16):6063-6076
Origin and Molecular Specification of Striatal Interneurons
Oscar
Marín,
Stewart A.
Anderson, and
John L. R.
Rubenstein
Department of Psychiatry, Nina Ireland Laboratory of Developmental
Neurobiology, Langley Porter Psychiatric Institute, University of
California, San Francisco, San Francisco, California 94143-0984
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ABSTRACT |
The striatum, the largest component of the basal ganglia, contains
projection neurons and interneurons. Whereas there is considerable agreement that the lateral ganglionic eminence (LGE) is the origin of
striatal projection neurons, less is known about the origin of striatal
interneurons. Using focal injections of retrovirus into the ventral
telencephalon in vitro, we demonstrate that most striatal interneurons tangentially migrate from the medial ganglionic eminence (MGE) or the adjacent preoptic/anterior entopeduncular areas
(POa/AEP) and express the NKX2.1 homeodomain protein. Although the
majority of striatal interneurons (cholinergic,
calretinin+, and parvalbumin+)
maintain the expression of NKX2.1 into adulthood, most of the interneurons expressing somatostatin (SOM), neuropeptide Y (NPY), and
neural nitric oxide synthase (NOS) appear to downregulate the
expression of NKX2.1 as they exit the neuroepithelium. Analysis of
striatal development in mice lacking Nkx2.1 suggests
that this gene is required for the specification of nearly all striatal interneurons. Similar analysis of mice lacking the Mash1
basic helix-loop-helix (bHLH) or both the Dlx1 and
Dlx2 homeodomain transcription factors demonstrates that
these genes are required for the differentiation of striatal
interneurons. Mash1 mutants primarily have a reduction
in early-born striatal interneurons, whereas Dlx1/2
mutants primarily have reduced numbers of late-born striatal
interneurons. We also present evidence implicating the Lhx6 and Lhx7 LIM-homeobox genes in the
development of distinct interneuron subtypes. Finally, we hypothesize
that, within the MGE, radially migrating cells generally become
projection neurons, whereas tangentially migrating cells mainly form
interneurons of the striatum and cerebral cortex.
Key words:
NKX2.1; DLX; MASH1; LHX; basal ganglia; interneuron; medial ganglionic eminence; lateral ganglionic eminence; striatum; neuron identity; neuronal specification; telencephalon
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INTRODUCTION |
The integration of complex
information within a neural system frequently requires the coordinated
activity of projection neurons and interneurons. In the striatum, the
largest component of the basal ganglia, projection neurons comprise
90% of the cells, give rise to its outputs, and receive nearly all of
the synapses from extrinsic striatal afferents as well as from the
striatal interneurons (for review, see Heimer, 1995 ; Parent and
Hazrati, 1995; Gerfen and Wilson, 1996). Interneurons, on the other
hand, comprise only ~10% of striatal cells and are implicated in
regulating striatal projection function (for review, see Kawaguchi et
al., 1995; Kawaguchi, 1997).
The mechanisms that control the generation of different striatal
neuronal subtypes and their assembly into functional circuits are
poorly understood. The basal ganglia (striatum and pallidum) derive
from both the lateral and the medial ganglionic eminences in the
telencephalon (LGE and MGE, respectively). Striatal projection neurons
are thought to derive from the LGE (Deacon et al., 1994; Olsson et al.,
1995, 1998; Anderson et al., 1997a), and Dlx1,2,5,6, Gsh2, Mash1, and retinoid receptor transcription
factors have been implicated in the control of their specification and
differentiation (Porteus et al., 1994; Hsieh-Li et al., 1995; Anderson
et al., 1997a; Szucsik et al., 1997; Casarosa et al., 1999; Eisenstat et al., 1999; Toresson et al., 1999). For instance, the Dlx
genes are homeodomain transcription factors that are expressed in
overlapping patterns during the differentiation of basal telencephalic
neurons (Anderson et al., 1997a; Eisenstat et al., 1999). Mice lacking Dlx1 and Dlx2 have a block in the differentiation
of late-born neurons in the basal telencephalon, which affects to a
large number of projection neurons of the striatum as well as
interneurons of the cerebral cortex and olfactory bulb (Anderson et
al., 1997a,b; Bulfone et al., 1998). In addition,
Mash1 encodes a basic helix-loop-helix transcription
factor that is required for the development of early-born neurons in
the basal telencephalon and some cortical interneurons (Casarosa et
al., 1999).
Unlike striatal projection neurons, the origin of striatal interneurons
and the genetic control of their development are poorly understood.
Striatal interneurons comprise four major classes: (1) cholinergic
neurons; (2) GABAergic neurons containing calretinin (CR); (3)
GABAergic neurons containing parvalbumin (PV); and (4) GABAergic
neurons containing somatostatin (SOM), neuropeptide Y (NPY), and
neuronal nitric oxide synthase (NOS) (for review, see Kawaguchi et al.,
1995) (but also see Figueredo-Cardenas et al., 1996). Previous
transplantation studies in the rat have suggested that
SOM+ interneurons mainly derive from the
LGE, whereas cholinergic interneurons may derive from the MGE (Olsson
et al., 1998). The origin of the GABAergic interneurons containing PV
or CR has not been elucidated. Recent studies have found that there are
migrations of cells from the MGE into the LGE (Sussel et al., 1999;
Wichterle et al., 1999), raising the possibility that some striatal
cells are derived from the MGE. Furthermore, the expression pattern of
the Nkx2.1 homeobox gene suggests that at least some of
these migrating cells may express this gene. Although it is known that Nkx2.1 is required for the specification of MGE derivatives
(Sussel et al., 1999), the analysis of striatal interneurons in this
mutant has not been described.
In this work we describe our studies that investigated the origin of
the four major types of striatal interneurons, and that demonstrates
the essential role of the Nkx2.1, Dlx1, Dlx2, and Mash1 transcription factors in controlling their
development. In addition, we also provide evidence that two different
LIM-homeodomain transcription factors, Lhx6 and
Lhx7, might control the development of distinct subtypes of
striatal interneurons. In toto, these results begin to
elucidate the pathway of transcription factors that control
specification and differentiation of striatal interneurons.
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MATERIALS AND METHODS |
Animals. C57BL/J6 mice were used for the organotypic
slice culture experiments and for immunohistochemical colocalization studies. In addition, mouse mutant strains with null alleles of Nkx2.1 (a gift of S. Kimura, National Cancer Institute,
Bethesda, MD), Mash1 (Guillemot et al., 1993), and
Dlx-1 and Dlx-2 (Qiu et al., 1997) were used for
the immunohistochemical localization of striatal interneurons. These
mutant strains were maintained by backcrossing to C57BL/J6 mice for at
least 10 generations. For staging of the embryos, midday of the vaginal
plug was considered as embryonic day 0.5 (E0.5). Mouse colonies were
maintained at University of California, San Francisco in accordance
with National Institutes of Health and UCSF guidelines.
Retrovirus preparation. The production of Moloney murine
leukemia virus/vesicular stomatitis virus G (MMLV/VSV-G) pseudotyped retrovirus has been described in detail previously (Ory et al., 1996).
Briefly, a replication-defective retroviral construct ( U3nlxLacZ) encoding a nuclear-localizing  -galactosidase (-gal) under the control of the human cytomegalovirus (HCMV) enhancer-promoter was
cotransfected into a 293-derived packaging cell line. Viral supernatants were harvested and concentrated by ultracentrifugation. Viral pellets were resuspended in PBS, and aliquots of virus were stored at  80°C.
Organotypic slice cultures. Organotypic slice cultures of
embryonic mouse telencephalon were prepared as previously described (Anderson et al., 1997a). Briefly, embryos (E12.5-E16.5) were removed
by cesarean section and decapitated. Brains were removed in ice-cold
Krebs' buffer, pH 7.4, containing (in mM) 126 NaCl, 2.5 KCl, 1.2 NaH2PO4, 1.2 MgCl2, 2.5 CaCl2, 11 glucose, and 25 NaHCO3. Then the brains were
embedded in 4% low melt point agarose (FMC Bioproducts, Rockland, MA),
and 250-µm-thick coronal sections were cut on a vibratome and
collected in ice-cold Krebs' buffer. The sections subsequently
were transferred to sterile ice-cold Krebs' buffer (filtered Krebs'
containing 10 mM HEPES, penicillin, streptomycin, and
gentamycin). After 15 min the sections were transferred to
polycarbonate culture membranes (13 mm diameter, 8 µm pore size;
Corning Costar, Cambridge, MA) in organ tissue dishes containing 1 ml
of medium with serum (Gibco MEM with glutamine, 10% fetal calf serum,
penicillin, and streptomycin). Subsequently, they were incubated for 1 hr in a sterile incubator (at 37°C in 5% CO2),
after which the medium was change to Neurobasal/B-27 (Life
Technologies, Gaithersburg, MD). Injections were performed immediately
after this step. Retroviruses were pressure-injected focally onto the
LGE or MGE by a pneumatic PicoPump (Narishige, Tokyo, Japan) through a
glass micropipette. After incubation for various times the slices were
fixed in 4% paraformaldehyde (PFA) in 0.1 M PBS for 1 hr
at 4°C and processed for -gal histochemistry or -gal/NKX2.1
double immunohistochemistry as described below. In control experiments
2 µg/µl of cytochalasin-D (Sigma, St. Louis, MO) was added to the
culture medium 12 hr after the injections to inhibit cell migration.
-Gal staining. -Gal histochemistry was performed in
free-floating sections at 37°C overnight in a solution containing
0.005% Na-deoxycholate, 0.01% Nonidet P40, 5 mM
K4Fe(CN)6, 5 mM
K3Fe(CN)6, 2 mM
MgCl2, and 0.8 mg/ml of
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-gal)
in 10 mM Tris-HCl buffer (TB), pH 7.3. Then the sections were rinsed in TB, fixed for 1 hr in 4% PFA, dehydrated, and cleared in xylene. For -gal/NKX2.1 double immunohistochemistry the
organotypic slice cultures were fixed, cryoprotected in 30% sucrose in
PBS, cut into 20 µm sections, and mounted onto Superfrost Plus slides (Fisher Scientific, Pittsburgh, PA). Then the sections were
preincubated in 5% normal goat serum (NGS), 1% bovine serum albumin
(BSA), and 0.2% Triton X-100 (TX) in PBS for 30 min at room
temperature; subsequently, they were incubated overnight at 4°C in a
cocktail of primary antisera diluted 1:1000 with 2% NGS and 0.2% TX
in PBS. Mouse anti--gal (Promega, Madison, WI) and rabbit
anti-NKX2.1 (Biopat Immunotechnologies, Caserta, Italy) antisera were
used. Sections were rinsed in PBS and incubated for 1 hr in a cocktail of Alexa 488 goat anti-mouse and Alexa 594 goat anti-rabbit secondary antisera (Molecular Probes, Eugene, OR) diluted 1:200 in the same solution as the primary antisera. Washings were performed in PBS, and
the sections were coverslipped with Prolong Antifade mounting medium
(Molecular Probes). In all cases, NKX2.1 immunoreactivity was used to
demarcate the mantle region of the MGE and the LGE.
Immunohistochemistry single labeling. E18.5 embryos, removed
by caesarean section, and neonates were anesthetized by cooling and
perfused with 4% PFA. Brains were removed and post-fixed for 3 hr,
cryoprotected in 30% sucrose in PBS, and cut frozen in the transverse
plane on a sliding microtome at 40-50 µm. Then free-floating sections were preincubated in 5% normal serum of the species in which
the secondary antibody was raised, 1% BSA, and 0.3% TX in PBS for 1 hr at room temperature; subsequently, they were incubated with the
primary antisera for 36 hr at 4°C in 2% normal serum and 0.3% TX in
PBS. The following antibodies were used: rabbit anti-CB (Swant,
Bellinzona, Switzerland), diluted 1:5000; rabbit anti-CR (Chemicon,
Temecula, CA), diluted 1:5000; goat anti-ChAT (Chemicon), diluted
1:100; rabbit anti-NPY (Incstar, Stillwater, MN), diluted 1:3000; rat
anti-SOM (Chemicon), diluted 1:250; and rabbit anti-NOS (Zymed, San
Francisco, CA), diluted 1:1000. Sections then were incubated in
biotinylated secondary antibodies (Vector Laboratories, Burlingame,
CA), diluted 1:200, and processed by the ABC histochemical method
(Vector Laboratories). The sections were mounted onto Superfrost Plus
slides (Fisher Scientific), dried, dehydrated, and coverslipped with
Permount (Fisher Scientific). In each experiment the sections from
homozygous mutants and their wild-type or heterozygous littermates were
processed together. Primary antiserum omission controls and normal
mouse, rabbit, and goat serum controls were used to confirm further the
specificity of the immunohistochemical labeling. Labeled cells were
plotted by using a system for image analysis (Openlab Improvision, UK). For counting the numbers of striatal interneurons in Nkx2.1
and Mash1 mutants, we analyzed two defined striatal levels
in three independent experiments. Wild-type and mutant striatal
sections were matched by using external anatomical references. At the
rostral striatal level, equivalent cortical and septal levels were used as landmarks. At the caudal striatal level, equivalent regions of the
hippocampus and preoptic area were used as landmarks. The mean striatal
area (mm2 ± SEM) at the rostral section
plane is 0.95 ± 0.12 for the wild-type and 1.1 ± 0.16 and
0.86 ± 0.09 for the Nkx2.1 and Mash1
mutants, respectively. At the caudal section plane the mean striatal
area (mm2 ± SEM) is 0.79 ± 0.08 in
wild-type mice and 0.85 ± 0.12 and 0.72 ± 0.11 in
Nkx2.1 and Mash1 mutant mice, respectively.
Because the area surface of the striatum in Dlx1/2 mutant
mice is relatively constant throughout the rostrocaudal extend of the
nucleus, a single level was analyzed in three independent experiments.
The cortex and septum were used as anatomical landmarks to match the rostrocaudal level from both wild-type and mutant sections. The mean
striatal area (mm2 ± SEM) is 0.81 ± 0.07 for the wild-type and 0.23 ± 0.03 for the Dlx1/2
mutant. The mean diameter (µm ± SEM) of striatal neurons is
9.22 ± 0.89 in wild-type and 9.32 ± 0.58, 9.36 ± 0.68, and 9.29 ± 0.56 in Nkx2.1, Mash1, and
Dlx1/2 mutant mice, respectively.
Immunohistochemistry double labeling. Mice 3-4 weeks old
were anesthetized with an overdose of chloral hydrate and perfused transcardially with 20 ml of 0.9% NaCl, followed by 60 ml of 4% PFA
in PBS. The brains were removed, post-fixed for 2 hr at 4°C, cryoprotected, and sectioned frozen in the transverse plane on a
sliding microtome at 30-40 µm. Free-floating sections were
preincubated in 5% normal serum of the species in which the secondary
antibody was raised, 1% BSA, and 0.4% TX in PBS for 1 hr at room
temperature; subsequently, they were incubated in a cocktail of primary
antisera for 36 hr at 4°C. The cocktail always includes a rabbit
anti-NKX2.1 antiserum, diluted 1:1000 in 2% normal serum and 0.4% TX
in PBS, and one of the following antisera: mouse anti-CB (Sigma),
diluted 1:1000; mouse anti-DARPP-32, diluted 1:15,000; mouse anti-CR
(Chemicon), diluted 1:1000; goat anti-ChAT (Chemicon), diluted 1:100;
sheep anti-NPY (Chemicon), diluted 1:1000; or rat anti-SOM (Chemicon), diluted 1:250. Then the sections were rinsed in PBS and incubated for 2 hr in a cocktail of secondary antibodies diluted 1:200 in the same
solution as the primary antisera. Alexa 488 goat anti-mouse and Alexa
594 goat anti-rabbit were used for NKX2.1 and CB, DARPP-32, CR, NPY, or
SOM double labeling, whereas Alexa 488 goat anti-rabbit and Alexa 594 donkey anti-goat (Molecular Probes) were used for NKX2.1 and ChAT
double labeling. After being rinsed in PBS, the sections were stained
with 50 µg/ml of Hoechst 33342 (Molecular Probes), mounted, and
coverslipped with Prolong Antifade mounting medium. Analysis of
colocalization of NKX2.1 with striatal markers was performed in three
defined striatal sectors (dorsomedial, dorsolateral, and ventral
striatum; 0.5 mm2 each) in two sections at
defined rostrocaudal levels of the striatum in a total of three mice.
The percentage of double-labeled cells (e.g., NKX2.1-ChAT
double-labeled/total ChAT neurons at the three rostrocaudal levels) is
averaged for the three mice. The mean number (± SEM) of neurons
counted for each marker per animal is as follows: CB, n = 327 ± 7.3; DARPP-32, n = 380.3 ± 5.8;
ChAT, n = 148.7 ± 11.6; PV, n = 65.3 ± 6.9; CR, n = 42 ± 4.7; NPY,
n = 187 ± 13.3; and SOM, n = 194.3 ± 10.2.
NADPH-diaphorase (NADPHd) staining. NADPHd histochemistry
was performed in free-floating sections at 37°C as previously
described (Marín et al., 1998). Briefly, E18.5 embryos and
neonates were anesthetized by cooling and were perfused with 4% PFA.
Brains were removed and post-fixed for 3 hr, cryoprotected in 30%
sucrose in PBS, and cut frozen in the transverse plane on a sliding
microtome at 40 µm. Then the free-floating sections were preincubated
in a medium containing 1 mM -NADPH (Sigma), 0.8 mM nitroblue tetrazolium (Sigma), and 0.06% TX in PBS at
37°C for 1-2 hr. After incubation the sections were rinsed
thoroughly in PBS, mounted, and, after drying overnight, were coverslipped.
5-Bromo-2'-deoxyuridine (BrdU) labeling. Pregnant females
were injected intraperitoneally with 40 mg/kg of BrdU (Sigma) and killed 30 min later, or gestation was continued to term. Embryos were removed by caesarean section and decapitated; their brains were
removed and fixed in 4% PFA in PBS overnight at 4°C. Neonates were
perfused as described above. In all cases the brains were cryoprotected
in 30% sucrose, cut into 10 µm sections, and mounted onto Superfrost
Plus slides. Then the sections were preincubated in 5% NGS, 1% BSA,
and 0.2% TX in PBS for 30 min at room temperature; subsequently, they
were incubated overnight at 4°C in a rabbit antiserum against NKX2.1
diluted 1:500 in 2% NGS and 0.2% TX in PBS. After being rinsed in
PBS, the sections were post-fixed in 4% PFA in PBS for 20 min and
subsequently were incubated with 2N HCl in PBS for 20 min at 37°C.
Then the sections were rinsed in PBS and incubated 2 hr in a mouse
anti-BrdU antibody (Chemicon) diluted 1:200 as before. After being
rinsed in PBS, the sections were incubated in a cocktail of Alexa 488 goat anti-mouse and Alexa 594 goat anti-rabbit secondary antibodies
diluted 1:200 in the same solution as the primary antisera. Washings
were performed in PBS, and the sections were stained with Hoechst and
coverslipped as above.
In situ RNA hybridization. In situ
hybridization experiments were performed by using
35S riboprobes on 10 µm frozen sections
as described previously (Bulfone et al., 1993). The cDNA probes used in
this study were Nkx2.1 (Shimamura et al., 1995),
Lhx6 and Lhx7 (kindly provided by V. Pachnis,
National Institute for Medical Research, London, UK), and
ENK (kindly provided by C. Gerfen, National Institute of
Mental Health, Bethesda, MD).
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RESULTS |
NKX2.1 expression in the basal telencephalon
Nkx2.1 expression is first detectable in the mouse
basal telencephalon at the 11 somite stage, at approximately E8.75
(Shimamura et al., 1995). Between E10.5 and E11.5 Nkx2.1 is
strongly expressed in several regions within the basal
telencephalon/medial ganglionic eminence (MGE), part of the septum,
anterior entopeduncular area (AEP), and preoptic area (POa) (Price et
al., 1992; Kohtz et al., 1998; Sussel et al., 1999) (see also Fig.
10A). In these structures Nkx2.1 is
expressed in both proliferative and postmitotic cells (Sussel et al.,
1999). Conversely, Nkx2.1 expression is not found at these
stages in cells of the lateral ganglionic eminence (LGE), a
proliferative zone that is thought to give rise to the striatum (Deacon
et al., 1994; Anderson et al., 1997a). From E13.5 the immature basal
telencephalic nuclei that express Nkx2.1 are clearly recognizable and include the globus pallidus, ventral pallidum, entopeduncular nucleus, substantia innominata/basal magnocellular region, anterior part of the bed nucleus of the stria terminalis, and
part of the septum (Puelles et al., 1999; Sussel et al., 1999).
Here we extended previous analyses by examining the expression of
NKX2.1 protein in detail. In the telencephalon NKX2.1 expression appeared to be restricted primarily to the cell nucleus (Fig. 1). From E14.5, NKX2.1 expression is
found in scattered cells of the striatum (Fig.
1A-C), despite the fact that it is not expressed in
the proliferative zones of the LGE at the time when striatal neurons
are born (mostly between E11 and E16 in the mouse; see references in
Semba et al., 1988; Sadikot and Sasseville, 1997). Thus BrdU injections
30 min before death at different developmental stages (E12.5-E16.5)
double-label NKX2.1+ cells in the MGE, but
not in the LGE (data not shown).
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Figure 1.
Developmental expression of Nkx2.1
RNA and protein in the basal telencephalon. A, RNA
in situ hybridization analysis of Nkx2.1
expression in a coronal section of the basal telencephalon at E14.5.
B, NKX2.1 protein distribution in an adjacent section to
that shown in A. C, A higher
magnification image of the outlined boxed region in
B. D-G, Expression of NKX2.1 in coronal
sections through the telencephalon of the mouse at P18.
ac, Anterior commissure; AcbSh, shell of
the nucleus accumbens; EZ, ependymal zone;
GP, globus pallidus; LGE, lateral
ganglionic eminence; MGE, medial ganglionic eminence;
S, septum; st, stria terminalis;
Str, striatum. Scale bar: A, B, F,
G, 200 µm; C, 100 µm; D, E,
300 µm.
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As development proceeds, NKX2.1 is maintained in a subpopulation of
striatal cells. In the postnatal brain
NKX2.1+ cells are found not only in the
pallidal components of the basal ganglia (Fig. 1D)
but also in scattered cells within the dorsal and ventral subdivisions
of the striatum (Fig. 1D-G). Immunoreactivity for
NKX2.1, however, is always stronger in the nuclei of pallidal than of
striatal neurons. In summary, NKX2.1-expressing cells are present in
the striatum, despite evidence that progenitor cells of this region
(LGE) do not express this protein.
NKX2.1 striatal cells migrate from the MGE and POa/AEP
Because the proliferative zone of the striatum (LGE) does not
express NKX2.1 before E16.5, we wondered whether this population of
striatal cells arrives via a tangential migration from the MGE. Our
previous study, using DiI labeling of MGE cells, suggested that there
is a tangential migration from the MGE to the LGE (Sussel et al.,
1999). However, that study did not resolve several important questions,
including the origin of the progenitors that give rise to the migrating
cells and their eventual phenotype. In addition, it is also possible
that striatal NKX2.1+ cells derive from
the LGE, but, in contrast to the cells originated in the MGE, they
start to express NKX2.1 only when they become postmitotic. To
distinguish between these possibilities, we studied the origin of
striatal NKX2.1+ cells by infecting
telencephalic slices with replication-incompetent retroviruses encoding
the marker -galactosidase (see Materials and Methods). These viruses
can integrate only into mitotically active cells, and thus this method
enables us to follow the movements of progenitor cells at different
times after their infection.
Retroviral vectors were injected into either the VZ/SVZ of the LGE or
the MGE in coronal slices from the telencephalon of E12.5-E16.5 mice
(Fig. 2A). After 20 hr
the infected cells were always located within a radius of 100-400 µm
from the injection site (n = 9 of 9; Fig.
2B-D), suggesting that retroviral particles do not
diffuse passively between different proliferative zones. By 60 hr
the cells were detected outside the proliferative zones, and their
number and distance from the injection site increased with time
(Fig. 2E-H). Blocking cell migration by the
addition of cytochalasin-D (0.5-1 mg/ml) resulted in no
-gal+ cells outside the injection site
(n = 8; data not shown).
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Figure 2.
NKX2.1+ cells migrate from the
MGE into the striatum in telencephalic slice cultures.
A, Retroviral injections into the LGE (left
side, arrow) and MGE (right side,
arrow) in a 250 µm coronal slice through the telencephalon of
an E12.5 mouse. B, Migration of
-gal+ cells 20 hr after retroviral injection in
the LGE (left side) and the MGE (right
side). C, D, Higher magnification
images of the outlined boxed regions in
B. E, F, Migration of
-gal+ cells 60 hr after retroviral injection in
the LGE (E) or the MGE (F).
G, H, Higher magnification images of the
outlined boxed regions in E and
F, respectively. Note that whereas both radially
(arrowhead) and tangentially (arrows)
migrating cells are observed after injection in the LGE (E,
G), most migrating cells migrate radially after MGE injection
at this age (F, H). I-P, A large
number of -gal+ cells migrating from the MGE to
the striatum are NKX2.1+
(N-P), whereas none of the cells is
NKX2.1+ after retroviral injection in the LGE
(I-L). I, M, DAPI-stained
sections (10 µm) obtained from a 250 µm coronal slide through the
telencephalon of an E14.5 mouse after retroviral injection into the LGE
(star, I) or the MGE
(star, M) and 70 hr in culture.
J, K, N, O, Higher
magnification images of the outlined boxed regions in
I and M, respectively. L,
P, Higher magnification images of the outlined
boxed regions in J, K, N, and
O, respectively. Arrows point to
double-labeled cells, whereas arrowheads show single
-gal+ cells. Cx, Cortex;
GP, globus pallidus; LGE, lateral
ganglionic eminence; MGE, medial ganglionic eminence;
Str, striatum. Scale bars: A,
B, E, F, 400 µm;
C, D, G, H, 300 µm; I,
M, 200 µm; J, K, N, O, 100 µm; L,
P, 40 µm.
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When retroviral particles were injected into the MGE,
-gal+ cells were observed to migrate
into the mantle of the striatum at all stages that were examined
(E12.5, E13.5, E14.5, and E16.5; n = 10 of 10; Fig.
2F,H,K; data not shown). Usually, between
50 and 100 cells were labeled per experiment. Approximately 50% of the
striatal -gal+ cells derived from the
MGE were also positive for NKX2.1 (Fig. 2I-L).
Moreover, viral injections into the adjacent POa/AEP (ventral to the
MGE) at E12.5 also double-labeled NKX2.1 cells in the striatal mantle
(n = 3 of 5; data not shown). In contrast, none of the -gal+ cells derived from the LGE
expressed NKX2.1 at any of the stages that were examined
(n = 14 of 14; Fig. 2M-P). Taken
together, these results suggest that striatal cells expressing NKX2.1
derive primarily from the MGE, although some NKX2.1 cells also
originate in the adjacent POa/AEP.
NKX2.1 is expressed in most striatal interneurons
Because the mammalian striatum contains several cell types with
different functional roles (Kawaguchi et al., 1995; Kawaguchi, 1997),
we analyzed the expression of NKX2.1 in the distinct subtypes of
striatal cells. We performed double-labeling experiments during the
third postnatal week in the mouse, when the neurochemical characteristics of the striatum begin to resemble those of adults (Liu
and Graybiel, 1992; Schlösser et al., 1999). First, we used CB
immunohistochemistry to identify striatal projection neurons. CB is a
calcium-binding protein that is expressed predominantly in
medium-sized spiny neurons of the striatal matrix (Gerfen, 1992).
Double-labeling experiments revealed that the medium-sized CB+ neurons of the striatum do not express
NKX2.1 (Fig. 3A). In addition, we analyzed the expression of NKX2.1 in striatal neurons containing DARPP-32. DARPP-32 is a D1 receptor-associated protein found in striatal projection neurons, including both substance P and
enkephalin-containing projection neurons in the patch and matrix
compartments, and is virtually absent from striatal interneurons
(Anderson and Reiner, 1991). No NKX2.1 was detected in
DARPP-32+ striatal neurons (Fig.
3B).
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Figure 3.
NKX2.1 is expressed in most striatal interneurons
(C-I), but not in striatal projection neurons
(A, B). Shown is colocalization of NKX2.1 and CB
(A, I), DARPP32 (B), ChAT
(C), PV (D), CR (E,
F), NPY (G), or SOM
(H) in the striatum of P18 mice.
Arrows show double-labeled cells, whereas
arrowheads indicate cells expressing only NKX2.1.
P, Patch. Scale bar for A-I, 40 µm.
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Double labeling revealed that all cholinergic striatal interneurons, as
identified by the presence of the synthetic enzyme ChAT, are labeled
for NKX2.1 also (Fig. 3C). In fact, all
ChAT+ neurons in the telencephalon are
labeled with NKX2.1 (data not shown). Like the cholinergic neurons, all
PV+ striatal interneurons were found to
contain NKX2.1 (Fig. 3D). In addition, the vast majority of
CR+ striatal interneurons also was
labeled for NKX2.1 (94.2 ± 1.2%; Fig. 3E), although a
small proportion of the CR+ neurons in the
striatum does not contain NKX2.1 at this age (Fig. 3F).
In contrast to the cholinergic, PV+, or
CR+ interneurons, ~90% of striatal
interneurons expressing SOM, NPY, and NOS do not express NKX2.1 at
postnatal day 18 (P18) (arrowheads in Fig.
3G,H). We found that only ~10% of the
SOM+ or NPY+
cells were immunolabeled for NKX2.1 (13.4 ± 1.4% for SOM;
11.3 ± 1.7% for NPY; arrows in Fig. 3H;
data not shown). Most of these cells were located in the ventral
striatum, although a few double-labeled cells also were found in the
dorsal striatum.
In addition to its expression in projection neurons of the matrix, CB
also is found in a small subpopulation of striatal NOS interneurons
(Bennett and Bolam, 1993; Kubota and Kawaguchi, 1993). These
CB+ neurons are larger and more intensely
stained than the striatal projection neurons and are distributed in
both the patch and the matrix compartments (Kiyama et al., 1990;
Bennett and Bolam, 1993; Kubota and Kawaguchi, 1993). In our
double-labeling experiments we found that a small number of
CB+ neurons contained NKX2.1
(arrows in Fig. 3I). As in the case of the
NPY/SOM/NOS cells immunolabeled for NKX2.1, the
CB+ neurons containing NKX2.1 were located
primarily in the ventral striatum, suggesting that they actually
represent a subpopulation of the striatal interneurons containing SOM,
NPY, and NOS.
To evaluate the relationship between NKX2.1 localization and
interneuronal phenotype in the striatum further, we performed similar
double-labeling experiments at earlier times of development. At P0 the
number of SOM+,
NPY+, or NOS+
neurons that also contain NKX2.1 is substantially higher than at
P18, in particular at rostral striatal levels (data not shown). Nevertheless, most SOM+ or
NPY+ striatal neurons do not contain
NKX2.1 at this age.
The results from these double-labeling experiments (Fig. 3) combined
with the cell migration assay (see Fig. 2) support the notion that
striatal cholinergic (ChAT+),
PV+, and CR+
interneurons derive from the MGE and that NKX2.1 might play an important role in their development. In addition, at least a
subpopulation of the NPY/SOM/NOS striatal interneurons also may derive
from the MGE. It is not clear, however, whether all striatal
interneurons containing SOM, NPY, and NOS may derive from the MGE but
downregulate the expression of NKX2.1 as they progressively
differentiate. To clarify this problem, we analyzed the distribution of
striatal interneurons in Nkx2.1 mutant mice.
Nkx2.1 mutants are defective in
striatal interneurons
In mice deficient for Nkx2.1, pallidal structures are
not detectable and the cerebral cortex has reduced numbers of
interneurons (Sussel et al., 1999). Because homozygous mutants die
immediately after birth, we analyzed the expression of interneuronal
markers in the striatum at E18.5. Although at this age several markers are either not cell type-specific (e.g., CB) (Liu and Graybiel, 1992)
or are not expressed (PV; Schlösser et al., 1999), we were able
to determine that cholinergic (ChAT+),
CR+, and
SOM/NPY/NOS+ interneurons are either
eliminated or severely reduced in the Nkx2.1 mutants.
ChAT+ interneurons were not found at any
rostrocaudal level in the striatum (compare Fig.
4A,D with
5A) nor in any region of the telencephalon, including the magnocellular nucleus, horizontal and
vertical limbs of the diagonal band of Broca, medial septum, or the
medial preoptic region (Fig. 4B,E; data not shown).
CR+ striatal interneurons were reduced
severely at caudal striatal levels (approximately sixfold reduction;
Figs. 4C,F, 5A) although some
CR+ cells were present at rostral striatal
levels (Fig. 5A). Finally, SOM/NPY/NOS-immunoreactive cells
are missing almost completely from the Nkx2.1 mutant
striatum (compare Figs. 4G,H, J,K and
5A); when present, there would be two or three
immunoreactive, abnormally large, and brightly stained cells in the
ventral striatum (data not shown). In addition, neurons expressing
NADPH-diaphorase (NADPHd), which is a marker of the
SOM/NPY/NOS+ interneurons, were not found
in the mutant striatum (see Fig. 4I,L). Thus, at
E18.5 the Nkx2.1 mutants appear to lack most striatal interneurons.
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Figure 4.
Loss of striatal interneurons in
Nkx2.1 mutant mice. A-C, G-I, Coronal
sections through the telencephalon of E18.5 wild-type fetuses showing
ChAT (A, B), CR (C), and NPY
immunoreactivity (G, H) and showing NADPHd
staining (I) in the rostral striatum
(G), caudal striatum (A, C, H,
I), and basal telencephalon (B).
D-F, J-L, Coronal sections through the telencephalon
of E18.5 Nkx2.1 / fetuses showing
loss of ChAT (D, E), CR (F), and
NPY immunoreactivity (J, K), and showing NADPHd
staining (L) in the rostral striatum
(J), caudal striatum (D, F, K, L),
and basal telencephalon (E).
Insets in A-C and F-I
show higher magnification images of neurons from the outlined
boxed regions. Cx, Cortex; ec,
external capsule; GP, globus pallidus;
MPO-HDB, medial preoptic region-horizontal limb of
the diagonal band; Str, striatum. Scale bar for
A-L, 100 µm.
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Figure 5.
Reduction of different striatal interneuron
subtypes in E18.5 Nkx2.1/ fetuses
(A) and P0
Mash1/ (B)
and Dlx1/2/
(C) newborns. Histograms show averages ± SEM of the numbers of specific types of striatal interneurons. In
A and B the cells were counted in two
defined sections of the striatum (rostral and caudal) in three
independent experiments in each case. Total represents
the collective consideration of both rostral and caudal sections. In
C the cells were counted in a single striatal level in
three independent experiments. In Control* we have taken
into account the fourfold reduction in striatal surface area in the
Dlx1/2 mutants (see Materials and Methods) by dividing
the number of striatal interneurons in the wild-type striatum by four.
BMC, Basal magnocellular complex.
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Striatal interneurons are reduced in
Mash1 mutants
Mash1 is a basic helix-loop-helix transcription
factor gene that is required for the development of subsets of neurons
in the peripheral nervous system and CNS (Guillemot et al., 1993; Sommer et al., 1995; Cau et al., 1997; Hirsch et al., 1998; Casarosa et
al., 1999). In the telencephalon Mash1 is expressed in the proliferative zones of the LGE and the MGE (Lo et al., 1991; Guillemot and Joyner, 1993; Porteus et al., 1994; Torii et al., 1999) (see also
Fig. 10B). Mice lacking Mash1 have a very
small MGE (Casarosa et al., 1999; Horton et al., 1999). Thus, if the
MGE is the source of most striatal interneurons, we hypothesized that
there would be a reduction in their number in Mash1 mutants.
We analyzed the expression of striatal interneuronal subtype markers at
P0, because Mash1 homozygous mutant mice die within hours
after birth. Mash1 mutants have a severe reduction of
NKX2.1+ striatal neurons (approximately
threefold reduction; Figs. 5B, 6A,D). In line with
these results, the number of cholinergic neurons in the striatum was
reduced severely in Mash1 mutants (approximately sixfold
reduction; Figs. 5B, 6B,E), as it was in
other basal telencephalic regions (~10-fold reduction; Figs.
5B, 6C,F; data not shown). In addition,
CR-immunoreactive cells are missing almost completely from the caudal
striatum in Mash1 mutants, although a few CR cells are
present in the rostral striatum (Figs. 5B,
6G,J). Finally, the number of striatal
SOM/NPY/NOS/NADPHd+ interneurons also was
reduced in Mash1 mutants (Fig. 5H,I,K,L; data not
shown). The reduction of NPY/SOM/NOS/NADPHd, as estimated via the
number of NPY+ neurons, was more prominent
at caudal (~4.5-fold reduction; Figs. 5B,
6H,K) than at rostral levels (approximately
twofold reduction; Figs. 5B, 6I,L). These
results suggest that the number of neurons that adopt an interneuronal
phenotype in the striatum is proportional to the number of
Nkx2.1 neurons that become postmitotic in the ventral
telencephalon.
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Figure 6.
Reduction of striatal interneurons in
Mash1 mutants. A-C, G-I, Coronal
sections through the telencephalon of P0 wild-type pups showing NKX2.1
(A), ChAT (B, C), CR
(G), and NPY immunoreactivity (H,
I) in the rostral striatum
(H), caudal striatum (A, B,
G-I), and basal telencephalon
(C). D-F, J-L, Coronal sections
through the telencephalon of P0
Mash1/ pups showing reduction of
NKX2.1 (D), ChAT (E, F), CR
(J), and NPY immunoreactivity (K,
L) in the rostral striatum (K), caudal
striatum (D, E, J, L), and basal telencephalon
(F). Insets in A, B, D, E,
G, J show higher magnification images of neurons from the
outlined boxed regions. Cx, Cortex;
ec, external capsule; GP, globus
pallidus; GP*, mutant GP; MPO-HDB, medial
preoptic region-horizontal limb of the diagonal band;
Str, striatum. Scale bar for A-L, 100 µm.
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The results from the colocalization studies, together with the data of
the expression of striatal interneuronal markers in Nkx2.1
and Mash1 mutants, strongly suggest that most striatal interneurons derive from the MGE/Nkx2.1 region. Furthermore,
most ChAT, CR, and PV striatal interneurons maintain the expression of
NKX2.1 into adulthood, whereas most NPY/SOM/NOS interneurons do not.
These results suggest that most NPY/SOM/NOS striatal interneurons derive from the MGE/Nkx2.1 region, but they downregulate the
expression of NKX2.1 shortly after leaving the proliferative zone of
the MGE. As described in the next section, the analysis of striatal interneurons in Dlx1/2 double mutants supports this hypothesis.
Dlx1/2 mutants provide evidence that striatal
NPY+/NKX2.1 interneurons are
derived from the MGE
Dlx-1 and Dlx-2 are homeobox transcription
factor genes that are expressed in the proliferative zones of the LGE
and MGE (Bulfone et al., 1993; Eisenstat et al., 1999) (see also Fig.
10C). Mice homozygous for a deletion of both genes
(Dlx1/2 mutants) have a time-dependent block in striatal
differentiation, resulting in the accumulation of late-born LGE neurons
within the proliferative zone (Anderson et al., 1997a). In addition, a
similar defect may occur in the MGE, as judged by the expression of
NKX2.1 at P0. In the telencephalon of control mice the
NKX2.1+ cells are located primarily in
part of the septum, globus pallidus, ventral pallidum, substantia
innominata, and the bed nucleus of the stria terminalis (Fig.
7A). The striatum also
contains scattered NKX2.1+ cells at all
rostrocaudal levels at this age (Fig. 7A). At P0 only a
small number of NKX2.1+ cells are located
in the proliferative region of the ventral telencephalon (Fig.
7A), except for the ventral aspect of the lateral ventricle
at rostral telencephalic levels, which continues to contain NKX2.1 in
the postnatal telencephalon (see Fig. 1G). In contrast,
Dlx1/2 mutants have a massive accumulation of
NKX2.1+ cells in the periventricular
region of the mutant MGE (MGE*). In this area NKX2.1 expression is
found both in the proliferative zone (SVZ*) and in large ectopic
accumulations of nonproliferating densely packed cells (Fig.
7D). Moreover, NKX2.1+ cells
spread dorsally through the LGE SVZ, expanding as far as the
pallial-subpallial boundary (data not shown).
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Figure 7.
NPY colocalizes with NKX2.1 in the MGE
proliferative zone of Dlx1/2 double mutants. A,
D, G, Coronal sections through the caudal striatum of P0 pups
showing NKX2.1 (A, D) and NPY immunoreactivity
(G) in wild-type (A) and
Dlx1/2 double mutants (D, G).
Periventricular neuronal ectopias express both NKX2.1 and NPY in
Dlx1/2 double mutants (stars in D,
G, I, J). I, J, Higher magnification
images of neuronal ectopias from the outlined boxed
regions. The basal telencephalon of Dlx1/2
mutants also contains cells that stain only for NPY
(arrowhead in G, I) or NKX2.1
(SVZ* in D, J). B, C, E,
F, Pregnant females received a single injection of BrdU at
E10.5 (B, E) or E13.5 (C, F), and
the location of labeled cells was analyzed at E19. Note that although
the E10.5 injection results in a similar pattern of labeled cells in
wild-type and Dlx1/2 mutant embryos, most of the cells
labeled by the E13.5 injection in the mutant do not migrate to the
mantle but remain within the periventricular region. The cells that
accumulate in the mutant MGE* are positive for NKX2.1
(H, higher magnification of the region
outlined in the boxed region in
F). ac, Anterior commissure;
Cx, cortex; ec, external capsule;
FStr, fundus striatum; GP, globus
pallidus; GP*, mutant GP; LGE, lateral
ganglionic eminence; LGE*, mutant LGE;
MGE, medial ganglionic eminence; MGE*,
mutant MGE; SI, substantia innominata;
Str, striatum; Str*, mutant striatum;
SVZ, subventricular zone; SVZ*, mutant
SVZ; VP, ventral pallidum. Scale bar: A, D,
G-J, 150 µm; B, C, E, F, 200 µm.
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An analysis of the migration properties of MGE-derived cells was
assessed by means of BrdU birthdating. Thus, pregnant animals received
a single injection of BrdU at E10.5, E11.5, E12.5, E13.5,and E15.5, and
the location of the BrdU-labeled cells was analyzed at birth. In the
ventral telencephalon of wild-type mice, E10.5 injections primarily
labeled cells in regions superficial to the striatum and pallidum (Fig.
7B); E11.5 and E12.5 injections labeled cells in the
pallidum (data not shown), whereas injections between E11.5 and E15.5
labeled cells throughout the striatum (Fig. 7B; data not
shown). In the Dlx1/2 mutants the early injections (E10.5 and E11.5) labeled cells in the striatum, pallidum, and regions superficial to the basal ganglia (Fig. 7E; data not shown);
in contrast, most of the mutant cells labeled by either the E12.5 or
E13.5 BrdU pulses remained within the mutant proliferative zone (Fig.
7F; data not shown). Of note, a large number of the cells
that accumulate in the mutant periventricular region are NKX2.1+ (star in Fig.
7H; also compare 7A and D).
These data indicate that, like in the LGE, Dlx1/2 mutants
have a time-dependent block in MGE differentiation, resulting in the
accumulation of late-born MGE neurons within the proliferative zone as
well as in periventricular neuronal ectopias (stars in Fig.
7D,G,I,J). Consistent with this conclusion is our
observation that the number of striatal cholinergic interneurons, which
are among the earliest-born cells of the striatum (Semba et al., 1988; Phelps et al., 1989), was less reduced in the Dlx1/2 mutants
(~2.5-fold reduction; Figs. 5C,
8A,C) than that of
later-born striatal NPY/SOM/NOS interneurons (Semba et al., 1988)
(approximately sixfold reduction; Figs. 5C,
8B,D). When the reduced surface area of the
Dlx1/2 mutant striatum is taken into account, the density of
striatal cholinergic interneurons is increased in Dlx1/2
mutants, whereas the density of striatal NPY/SOM/NOS interneurons is
reduced (see Fig. 5C).
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Figure 8.
Reduction of striatal interneurons in
Dlx1/2 double mutants. A, B, Coronal
sections showing ChAT (A) and NPY
immunoreactivity (B) in the striatum of P0
wild-type embryos. C, D, Coronal sections showing
reduction of ChAT (C) and NPY immunoreactivity
(D) in the striatum of P0 Dlx1/2
mutant embryos. The dashed line outlines the approximate
perimeter of the striatal mantle (based in part on being PCNA-negative;
data not shown) in Dlx1/2 mutants. Insets
in A-D show higher magnification images of neurons from
the outlined boxed regions. Note that
ChAT+ interneurons are grouped mainly in striatal
patches in both wild-type and mutant embryos (arrowheads
in A, C). Cx, Cortex; S,
septum; Str, striatum; Str*, mutant
striatum; SVZ, subventricular zone; SVZ*,
mutant SVZ. Scale bar for A-D, 250 µm.
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Analysis at P0 shows that most of the cells that accumulated in the MGE
SVZ* in the Dlx1/2 mutants express NPY, SOM, NOS, and NKX2.1
(Fig. 7G,I,J; data not shown). In fact,
double-labeling experiments demonstrated that NPY and SOM are
coexpressed with NKX2.1 in this region (Fig. 7D,G,I,J; data
not shown). Therefore, in line with the previous experiments, the
analysis of NPY/SOM/NOS striatal neurons in Dlx1/2 mutants
suggests that this subtype of striatal interneurons derives primarily
from NKX2.1+ progenitors.
The expression of LIM homeodomain genes Lhx6 and
Lhx7 is differentially affected in Dlx1/2
double mutants
Whereas expression of Nkx2.1 in the basal telencephalon
is required for the formation of most striatal and cortical
interneurons (Sussel et al., 1999; present study), nothing is known
about the factors that control the differentiation of distinct
interneuron subtypes in the telencephalon. In the spinal cord a
combinatorial code of homeodomain (LIM, Nkx, Pax)
transcription factors controls the identity of different types of
ventral neurons (see Tanabe and Jessell, 1996; Briscoe et al., 1999).
In the basal ganglia the LIM proteins Lhx6 and Lhx7
are expressed in the developing MGE (Grigoriou et al., 1998; Lavdas et
al., 1999; Sussel et al., 1999; O. Marín and J. L. Rubenstein, unpublished observations) as well as in subsets of neurons
in the striatum (Fig.
9A,B,G,H).
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Figure 9.
Expression of the LIM homeodomain genes
Lhx6 and Lhx7 in the striatum of
Nkx2.1 mutants and Dlx1/2 double mutants.
A-C, G-I, Serial coronal sections through the
telencephalon of an E18.5 wild-type fetus showing Lhx7
(A), Lhx6
(B), and ENK
(C) expression in the striatum, and of a P0 pup
showing Lhx7 (G),
Lhx6 (H), and
Nkx2.1 (I) expression in
the basal telencephalon. D-F, Serial coronal sections
from an E18.5 Nkx2.1 mutant showing loss of
Lhx7 (D) and Lhx6
(E) expression and normal ENK
(F) expression in the expanded striatum.
J-L, Serial coronal sections from a P0
Dlx1/2 mutant showing normal Lhx7
(J) expression and reduced Lhx6
(K) and Nkx2.1
(L) expression in the striatum.
G-L, The dashed line outlines the
approximate perimeter of the striatal mantle. Note that
Lhx6 expression accumulates in periventricular neuronal
ectopias that also express Nkx2.1 (stars
in K, L), but not Lhx7
(J). J-L, The dashed
line approximates the extension of the striatal mantle in
Dlx1/2 mutants. Cx, Cortex;
DB, diagonal band; HC, hippocampus;
OT, olfactory tubercle; GP, globus
pallidus; GP*, mutant GP; Str, striatum;
Str*, mutant striatum; SVZ,
subventricular zone; SVZ*, mutant SVZ;
VP, ventral pallidum; VP*, mutant VP.
Scale bar for A-L, 500 µm.
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To define the relationship between transcription factor expression and
neuronal identity in the striatum, we analyzed the expression of
Lhx6 and Lhx7 in the striatum of
Nkx2.1 mutants at E18.5. In these mutants the cells
expressing Lhx6 or Lhx7 were not found at any
rostrocaudal level in the striatum (Fig. 9D,E). Because
Nkx2.1 is not expressed in striatal projection neurons (see
Fig. 3A,B) and it apparently is not required for their
proper differentiation (Fig. 9C,F) (Sussel et al.,
1999), these results suggest that Lhx6 and Lhx7
expression most likely is confined to local circuit neurons in the striatum.
Next, we examined Lhx6 and Lhx7 expression in
Dlx1/2 mutants. At birth,
Lhx6+ cells were found in reduced
numbers in the mutant striatum, whereas Lhx7 expression was
approximately normal or even increased (Fig. 9G,H,J,K). Moreover, both NPY/SOM/NOS and
Lhx6 were expressed abnormally in the periventricular region
(see Figs. 7G,J, 9K), suggesting that this
transcription factor might be involved in the development of
NPY/SOM/NOS interneurons. The expression of Lhx7 in
Dlx1/2 mutants suggests, on the other hand, that this transcription factor is involved in the development of a different subset of interneurons (e.g., the ChAT+
neurons, which are not present in the periventricular region of
Dlx1/2 mutants) (see Fig. 7A,C).
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DISCUSSION |
In this study we provide evidence that the vast majority of
striatal interneurons migrates tangentially from progenitor zones in
the MGE and POa/AEP to the postmitotic zone of the LGE.
Nkx2.1, which is expressed in progenitor zones of the MGE
and POa/AEP and in most mature striatal interneurons, is required for
the development of nearly all striatal interneurons. In contrast, Mash1 and Dlx1/2, which also are expressed in the
precursor cells of this region, regulate the development of early-
versus late-born interneurons, respectively. Finally, our analysis
implicates distinct LIM homeobox genes (Lhx6 and
Lhx7) in the generation of specific subtypes of
striatal interneurons.
Most striatal interneurons are derived from
NKX2.1+ precursors in the MGE and POa/AEP and
tangentially migrate into the striatum
Recent DiI labeling and transplantation experiments have revealed
a robust tangential migration from the MGE to the LGE (Lavdas et al.,
1999; Sussel et al., 1999; Wichterle et al., 1999). Here we show, using
retroviral cell tracing (see Fig. 2), that cells emanating from the MGE
and the adjacent POa/AEP migrate to the developing striatum, where they
differentiate into local circuit neurons. Furthermore, this analysis
reveals that most striatal cells derived from the MGE/POa/AEP express
Nkx2.1, whereas none of the LGE-derived cells do.
What subtypes of striatal interneurons derive from the MGE/POa/AEP? In
the adult striatum all cholinergic and PV+
and nearly all CR+ interneurons coexpress
NKX2.1. In contrast, only ~10% of the NPY/SOM/NOS/NADPHd
interneurons contain NKX2.1. These static histochemical analyses
suggest that all cholinergic and PV+, most
CR+, and some NPY/SOM/NOS/NADPHd striatal
interneurons are derived from the MGE/POa/AEP, whereas the LGE is the
source of the majority of the NPY/SOM/NOS/NADPHd and some
CR+ striatal interneurons. Of note,
striatal NPY/SOM/NOS/NADPHd interneurons do not develop in
Nkx2.1 mutants, raising the possibility that some striatal
interneurons might derive from regions other than the MGE (e.g., LGE)
but require substances produced from a normal MGE to differentiate
and/or survive.
An alternative possibility is, however, that most striatal interneurons
actually derive from the MGE/POa/AEP, but some of them (expressing
NPY/SOM/NOS/NADPHd) downregulate the expression of Nkx2.1
after leaving the proliferative zone. Three independent lines of
evidence support this hypothesis: (1) In the absence of
Nkx2.1 the striatum does not contain cholinergic or
NPY/SOM/NOS/NADPHd interneurons (see Fig. 4); (2) NKX2.1 and NPY/SOM
are coexpressed in partially differentiated cells in the proliferative
zone of Dlx1/2 mutants (see Fig. 7; also discussed below);
and (3) paleo-, neo-, and archicortical interneurons derived from the
MGE do not express Nkx2.1, suggesting that they downregulate
its expression after leaving the proliferative zone (Sussel et al.,
1999; S. Anderson, O. Marín, and J. L. Rubenstein,
unpublished observations). In summary, we suggest that nearly all
striatal interneurons are derived from the MGE/POa/AEP region. The only
exception may be a few CR+ interneurons
for which the origin is not known.
Our data differ from some of the conclusions of an earlier study that
used transplantation experiments to investigate the origins of rat
cholinergic and SOM+ striatal interneurons
(Olsson et al., 1998). In agreement with our results, striatal
cholinergic interneurons were found mainly in grafts derived from the
early MGE (E12.5 in the rat; Olsson et al., 1998). In contrast, Olsson
and colleagues (1998) suggest that striatal
SOM+ interneurons are generated from both
the LGE and MGE. However, because SOM+
striatal interneurons are born as early as E12 in the rat (Semba et
al., 1988), it is possible that in the experiments described by Olsson
et al. (1998) the transplanted LGE already had MGE-derived cells within it.
Dlx1, Dlx2, and Mash1
regulate the generation of early- and late-born striatal
interneurons
Dlx1, Dlx2, and Mash1 are expressed in
progenitor cells of the LGE and MGE (Porteus et al., 1994; Liu et al.,
1997; Eisenstat et al., 1999; Torii et al., 1999).
Dlx1/2 double mutants previously were shown to have a
time-dependent block in the differentiation of radially migrating
striatal projection neurons and tangentially migrating cortical local
circuit neurons (Anderson et al., 1997a,b). Mash1 mutants
have a complementary defect that affects the generation of early-born
neurons in the ventral telencephalon (Casarosa et al., 1999). Here we
show that these mutants have similar time-dependent defects in the
generation of the MGE-derived striatal interneurons (see Figs. 5-8).
In addition, the Dlx1/2 mutants accumulate periventricular ectopia of partially differentiated neurons deep to the subventricular zone (see Fig. 7). As noted above, these ectopia contain cells that are
NKX2.1+/NPY+,
implying that Dlx1/2 are required (directly or indirectly)
to enable these striatal interneurons to repress Nkx2.1
expression. We suggest that Mash1 and Dlx1/2
regulate the balance between early versus late differentiation in the
basal telencephalon (K. Yun and J. L. Rubenstein, unpublished
observations), whereas Nkx2.1 regulates regional and
cell-type specification in this region (Fig.
10).
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Figure 10.
Schemas illustrating the origin and migration of
neurons derived from the NKX2.1+ proliferative
region in the basal telencephalon and the genes that are involved in
their specification and differentiation. A-C, These
drawings are based on a coronal section of a mouse E12.5 right
telencephalic hemisphere. The light gray arrow-tipped
lines indicate early (E) and late
(L) tangential migrations that originate in the
NKX2.1+ progenitor zone (dark gray)
of the MGE and POA/AEP. A dashed line indicates the
limit between the VZ and SVZ. A, Both tangential
migrations are lost (indicated by black Xs) in the
Nkx2.1 mutant mouse because of a ventral-to-dorsal
respecification of the progenitor zone (Sussel et al.; 1999).
B, The Mash1 mutation preferentially
blocks the early (E) tangential migration. MASH1
expression is in a subset of VZ cells (light gray) and
in most SVZ cells (dark gray). C, The
Dlx1/2 mutation preferentially blocks the late
(L) tangential migration. DLX1 and DLX2
expression is in a subset of VZ cells (light gray) and
in most SVZ cells (dark gray). D, Schema
of a coronal section through an E12.5 mouse telencephalon. The
NKX2.1+ VZ is indicated in light
gray. Migrations of GABAergic cells from the
NKX2.1+ progenitor zone are indicated on the
left. A radial migration produces the GABAergic
projection neurons of the globus pallidus (GP), whereas
tangential migrations produce GABAergic interneurons of the striatum
(this study) and cerebral cortex (Anderson et al., 1999; Sussel et al.,
1999; Anderson, Marín, and Rubenstein, unpublished
observations). Although the origin of some cortical interneuron
subtypes, such as those containing PV or VIP, has not been
demonstrated, we hypothesize that they also may derive from the basal
telencephalon. Migrations of cholinergic (ChAT)
cells from the NKX2.1+ progenitor zone are indicated
on the right. A radial migration produces the
cholinergic projection neurons of the basal magnocellular complex
(BMC), whereas tangential migrations produce cholinergic
interneurons of the striatum (this study). E, Model
describing some of the genes that regulate the production of
tangentially migrating cells from NKX2.1+ progenitor
cells. Dlx1/2 and Mash1 regulate the
production of secondary progenitor cells that express
Lhx6 and Lhx7 (we do not know whether a
single cell expresses both Lhx genes). From these cells
we hypothesize that three types of interneurons are formed, two of
which migrate to the striatum and a third that contributes interneurons
to both the striatum and cortex. CB, Calbindin;
CR, calretinin; Cx, cortex;
NOS, nitric oxide synthase; NPY,
neuropeptide Y; Pd, pallidum; PV,
parvalbumin; SOM, somatostatin; Str,
striatum; SVZ, subventricular zone; VIP,
vasointestinal peptide; VZ, ventricular zone.
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Specification of neuronal identity in the MGE/POa/AEP
Fate maps of the early telencephalon support the hypothesis that
derivatives of the MGE/POa/AEP include the dorsal pallidum, ventral
pallidum, and basal magnocellular complex (Rubenstein et al.,
1998; I. Cobos, K. Shimamura, J. L. Rubenstein, L. Puelles, and S. Martínez, unpublished observations). In the present
study we have shown that this NKX2.1+
region gives rise to neurons that express either acetylcholine or GABA.
It is unknown what controls the switch between these two
phenotypes. In addition, each of these two cell types gives rise to
cells that are either radially migrating projection neurons or local
circuit neurons that migrate tangentially to the striatum and cerebral
cortex (Fig. 10D) (Anderson et al., 1997b; Lavdas et
al., 1999; Sussel et al., 1999; present study).
Thus, the basal telencephalon contains two main types of cholinergic
neurons, the local circuit neurons of the striatum and the projection
neurons of the basal forebrain system, including the nucleus basalis
magnocellularis, diagonal band, and medial septum (Mesulam et al.,
1983a,b; 1984). Although the cholinergic neurons of the striatum and
basal forebrain system are located within different nuclei and are
known to have very different functions, they are generated at
approximately the same time (Semba et al., 1988; Brady et al., 1989;
Phelps et al., 1989). Moreover, the present data demonstrate that
cholinergic neurons in the ventral telencephalon derive from a common
germinal source, the MGE/POa/AEP region, and that their development
requires Nkx2.1 function.
As in the case of the cholinergic neurons, the neurotransmitter GABA is
expressed both in local circuit and projection neuronal populations of
the basal telencephalon that may share a common origin. For example,
GABA is expressed in subsets of striatal interneurons and globus
pallidus projection neurons (Kita and Kitai, 1994; Kawaguchi et
al., 1995; Parent and Hazrati, 1995); in both cases their development
appears to be dependent on Nkx2.1 function (Sussel et al.,
1999; present study; Marín and Rubenstein, unpublished observations).
It has been proposed that neurons sharing the same chemical phenotype
(e.g., cholinergic neurons) from different areas of the telencephalon
are neurogenetically homologous and that their final morphology and
connectivity depend primarily on extrinsic factors (Gähwiler and
Hefti, 1985; Semba et al., 1988; Campbell et al., 1995; Sadikot and
Sasseville, 1997). An alternative model is that intrinsic factors
distinguish projection and interneurons, even when they share the same
neurotransmitter phenotype. This would be necessary to explain their
distinct migratory pathways. For instance, basal forebrain cholinergic
and pallidal GABAergic projection neurons are superficial to the
progenitor zones from which they derive and thus seem to follow a
radial migration, whereas cholinergic and GABAergic interneurons
migrate tangentially to the striatum.
What are the genes that regulate the choice between becoming a radially
migrating projection neuron or a tangentially migrating local circuit
neuron? The answer to this question is not known, but clues may be
provided by studies of dorsoventral patterning of the spinal cord and
hindbrain. In these structures Nkx genes (Nkx2.2
and Nkx6.1) specify the identity of the progenitor cells of
distinct longitudinal domains in the ventral neural tube (Qiu et al.,
1998; Briscoe et al., 1999; M. Sander, S. Paydar, J. Ericson, J. Briscoe, E. Berber, M. German, T. Jessell, and J. Rubenstein, unpublished observations). Nkx6.1 is upstream of several
homeodomain transcription factors that are required for the development
of projection neurons (cholinergic motor neurons) and interneurons (V2
cells) (Sander, Paydar, Ericson, Briscoe, Berber, German, Jessell, and
Rubenstein, unpublished observations). Among the downstream
genes are Isl1 and Lhx3, which encode
LIM-homeodomain proteins that have essential roles in motor neuron
development (Pfaff et al., 1996; Sharma et al., 1998).
The combinatorial expression of LIM-homeodomain proteins defines
specific populations of neurons in the ventral CNS (Tsuchida et al.,
1994; Appel et al., 1995; Tanabe and Jessell, 1996).
These results drew our attention to the Lhx6 and
Lhx7 LIM-homeobox genes, which are expressed in the MGE and
are dependent on Nkx2.1 function (Sussel et al., 1999).
Thus, these genes are candidates for defining cell type specification
within the basal telencephalon. However, they are expressed both in
pallidal projection neurons and tangentially migrating interneurons
(see Fig. 9), implying that other factors are required to define
projection neurons from interneurons. At this point the intrinsic
factors that determine whether a cell migrates radially or tangentially are not known. On the other hand, there is evidence that the secreted molecule SLIT1 regulates the radial migration of GABAergic neurons derived from the LGE (Zhu et al., 1999).
Although Lhx6 and Lhx7 may not regulate the
choice between projection and interneurons, they may have a role in
regulating the development of distinct subsets of striatal interneurons
(Fig. 10E). We base this hypothesis on our
observations of their expression in the Dlx1/2 mutants. In
these animals the patterns of Lhx6 and NPY/SOM/NOS
expression are correlated (see Figs. 7G,I,J,
9K), whereas the expression of Lhx7
correlates with the distribution of ChAT+
neurons (see Figs. 8C, 9J).
Telencephalic GABAergic and cholinergic interneurons are derived
from the basal ganglia
The results of this and other studies strongly suggest that the
basal ganglia primordia are the origin of the majority of interneurons
present in the mature striatum, cortex, and olfactory bulb (de Carlos
et al., 1996; Anderson et al., 1997b, 1999; Tamamaki et al., 1997;
Casarosa et al., 1999; Lavdas et al., 1999; Sussel et al., 1999;
Wichterle et al., 1999; Anderson, Marín, and Rubenstein, unpublished observations). Several lines of evidence suggest that the
MGE is a major source of tangentially migrating interneurons to both
the striatum and cortex (Anderson et al., 1999; Lavdas et al., 1999;
Sussel et al., 1999; Wichterle et al., 1999; Anderson, Marín,
and Rubenstein, unpublished observations). Interestingly, the LGE
appears to be the source of a different pool of cortical and olfactory
bulb interneurons, as demonstrated by the comparative analysis of
Dlx1/2 and Nkx2.1 mutants (Anderson et al.,
1997a,b, 1999; Sussel et al., 1999; Anderson, Marín, and
Rubenstein, unpublished observations).
Theoretical issues
The findings described in this and other studies (de Carlos et
al., 1996; Anderson et al., 1997b, 1999; Tamamaki et al., 1997; Casarosa et al., 1999; Lavdas et al., 1999; Sussel et al., 1999; Wichterle et al., 1999; Anderson, Marín, and Rubenstein,
unpublished observations) raise several interesting theoretical issues.
First, whereas radially migrating cells could translate the positional information values of their precursors to the overlying mantle zone,
tangentially migrating cells would not. Thus, tangentially migrating
local circuit neurons may not have a role in the initial formation of
topographic connectivity maps, whereas radially migrating cells do.
Second, why are striatal, cortical, and olfactory bulb interneurons
generated in the basal telencephalon, instead of locally? It may be
that cell type specification is tightly coupled to regional specification. Thus, induction of the transcription factors that regulate development of cholinergic neurons (e.g., Nkx2.1)
(Sussel et al., 1999; this study) and GABAergic neurons (e.g.,
Dlx1 and Dlx2) (Anderson et al., 1997a,b, 1999;
Bulfone et al., 1998) may take place only in proximity to morphogens
that are implicated in specification of the basal telencephalon (e.g.,
SHH) (Ericson et al., 1995; Chiang et al., 1996; Shimamura and
Rubenstein, 1997; Kohtz et al., 1998). This would imply that the
LGE is incapable of producing cholinergic cells and that the cortex is
incapable of producing GABAergic cells, thus requiring that these cell
types tangentially migrate from proliferative zones where they can be produced.
| |
FOOTNOTES |
Received Feb. 28, 2000; revised May 17, 2000; accepted May 19, 2000.
This work was supported by research grants to J.L.R.R. from Nina
Ireland, National Alliance for Research on Schizophrenia and
Depression, National Institute on Drug Abuse (R01 DA12462), and
National Institute of Mental Health (NIMH; R01 MH49428-01, R01
MH51561-01A1, and K02 MH01046-01); and to S.A. from NIMH (K08-MH01620). O.M. is supported by a postdoctoral fellowship from the Spanish Ministerio de Educación y Ciencia. We are very grateful to
J. E. Johnson for providing the Mash1 mutant mice;
to H. Hemmings for the DARPP-32 antibody; to D. H. Lowenstein for
the LacZ-expressing pseudotyped retrovirus; to A. Bagri for help with
the retrovirus injection and manipulation; to C. Horn for technical
help on the preparation of slice cultures; to L. Lu for help with mice
genotyping; to V. Pachnis (Lhx6 and
Lhx7) and C. Gerfen (ENK)
for mouse cDNA; and to members of the Rubenstein's lab for helpful
comments and discussions.
Correspondence should be addressed to Dr. John L. R. Rubenstein,
Department of Psychiatry, Nina Ireland Laboratory of Developmental Neurobiology, Langley Porter Psychiatric Institute, Box F-0984, University of California, San Francisco, 401 Parnassus Avenue, San
Francisco, CA 94143-0984. E-mail: jlrr{at}cgl.ucsf.edu.
| |
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R. Lonigro, D. Donnini, E. Zappia, G. Damante, M. E. Bianchi, and S. Guazzi
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M. Denaxa, C.-H. Chan, M. Schachner, J. G. Parnavelas, and D. Karagogeos
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H. Wichterle, D. H. Turnbull, S. Nery, G. Fishell, and A. Alvarez-Buylla
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O. Marin, A. Yaron, A. Bagri, M. Tessier-Lavigne, and J. L. R. Rubenstein
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T. Hamasaki, S. Goto, S. Nishikawa, and Y. Ushio
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T. Hamasaki, S. Goto, S. Nishikawa, and Y. Ushio
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S. Anderson, O Marin, C Horn, K Jennings, and J. Rubenstein
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K Yun, S Potter, and J. Rubenstein
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A. S. Kim, S. A. Anderson, J. L. R. Rubenstein, D. H. Lowenstein, and S. J. Pleasure
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TOP
ABSTRACT
INTRODUCTION
Substance via MeSH
